Recurrent hemichorea in an adolescent with systemic lupus erythematosus and previous ipsilateral cerebral infarction.

Systemic lupus erythematosus (SLE) can present with movement disorders, among which chorea is closely associated with antiphospholipid (aPL) antibodies. Brain imaging results obtained in patients with chorea are generally inconsistent with the clinical manifestation of chorea; moreover, medical tests for hemichorea, which are expected to reveal distinct localization, may show negative findings. Herein, we present a case of a 15-year-old girl with SLE who had a history of left cerebral infarction; tests revealed elevated aPL levels, and she developed recurrent left hemichorea 2 years later. Brain magnetic resonance imaging (MRI) results revealed no acute lesions during each episode of involuntary movements, and an MRI perfusion scan failed to provide an explanation for the asymmetric presentation. Although various hypotheses have been proposed regarding the mechanism underlying the occurrence of chorea, some scenarios still remain unexplained. Further investigation on the pathophysiology of chorea in SLE may be warranted to clarify its prognosis.

Cell activation-based screening of natively paired human T cell receptor repertoires.

Adoptive immune therapies based on the transfer of antigen-specific T cells have been used successfully to treat various cancers and viral infections, but improved techniques are needed to identify optimally protective human T cell receptors (TCRs). Here we present a high-throughput approach to the identification of natively paired human TCRα and TCRß (TCRα:ß) genes encoding heterodimeric TCRs that recognize specific peptide antigens bound to major histocompatibility complex molecules (pMHCs). We first captured and cloned TCRα:ß genes from individual cells, ensuring fidelity using a suppression PCR. We then screened TCRα:ß libraries expressed in an immortalized cell line using peptide-pulsed antigen-presenting cells and sequenced activated clones to identify the cognate TCRs. Our results validated an experimental pipeline that allows large-scale repertoire datasets to be annotated with functional specificity information, facilitating the discovery of therapeutically relevant TCRs.

Quality Control: Chain Pairing Precision and Monitoring of Cross-Sample Contamination: A Method by the AIRR Community.

New approaches in high-throughput analysis of immune receptor repertoires are enabling major advances in immunology and for the discovery of precision immunotherapeutics. Commensurate with growth of the field, there has been an increased need for the establishment of techniques for quality control of immune receptor data. Our laboratory has standardized the use of multiple quality control techniques in immunoglobulin (IG) and T-cell receptor (TR) sequencing experiments to ensure quality control throughout diverse experimental conditions. These quality control methods can also validate the development of new technological approaches and accelerate the training of laboratory personnel. This chapter describes multiple quality control techniques, including split-replicate cell preparations that enable repeat analyses and bioinformatic methods to quantify and ensure high sample quality. We hope that these quality control approaches can accelerate the technical adoption and validated use of unpaired and natively paired immune receptor data.

Immortalization and functional screening of natively paired human T cell receptor repertoires.

Functional analyses of the T cell receptor (TCR) landscape can reveal critical information about protection from disease and molecular responses to vaccines. However, it has proven difficult to combine advanced next-generation sequencing technologies with methods to decode the peptide-major histocompatibility complex (pMHC) specificity of individual TCRs. We developed a new high-throughput approach to enable repertoire-scale functional evaluations of natively paired TCRs. In particular, we leveraged the immortalized nature of physically linked TCRα:ß amplicon libraries to analyze binding against multiple recombinant pMHCs on a repertoire scale, and to exemplify the utility of this approach, we also performed affinity-based functional mapping in conjunction with quantitative next-generation sequencing to track antigen-specific TCRs. These data successfully validated a new immortalization and screening platform to facilitate detailed molecular analyses of disease-relevant antigen interactions with human TCRs.

The interplay of protein engineering and glycoengineering to fine-tune antibody glycosylation and its impact on effector functions.

The N-glycan pattern of an IgG antibody, attached at a conserved site within the fragment crystallizable (Fc) region, is a critical antibody quality attribute whose structural variability can also impact antibody function. For tailoring the Fc glycoprofile, glycoengineering in cell lines as well as Fc amino acid mutations have been applied. Multiple glycoengineered Chinese hamster ovary cell lines were generated, including defucosylated (FUT8KO), α-2,6-sialylated (ST6KI), and defucosylated α-2,6-sialylated (FUT8KOST6KI), expressing either a wild-type anti-CD20 IgG (WT) or phenylalanine to alanine (F241A) mutant. Matrix-assisted laser desorption ionization-time of flight mass spectrometry characterization of antibody N-glycans revealed that the F241A mutation significantly increased galactosylation and sialylation content and glycan branching. Furthermore, overexpression of recombinant human α-2,6-sialyltransferase resulted in a predominance of α-2,6-sialylation rather than α-2,3-sialylation for both WT and heavily sialylated F241A antibody N-glycans. Interestingly, knocking out α-1,6-fucosyltransferase (FUT8KO), which removed core fucose, lowered the content of N-glycans with terminal Gal and increased levels of terminal GlcNAc and Man5 groups on WT antibody. Further complement-dependent cytotoxicity (CDC) analysis revealed that, regardless of the production cells, WT antibody samples have higher cytotoxic CDC activity with more exposed Gal residues compared to their individual F241A mutants. However, the FUT8KO WT antibody, with a large fraction of bi-GlcNAc structures (G0), displayed the lowest CDC activity of all WT antibody samples. Furthermore, for the F241A mutants, a higher CDC activity was observed for α-2,6- compared to α-2,3-sialylation. Antibody-dependent cellular cytotoxicity (ADCC) analysis revealed that the defucosylated WT and F241A mutants showed enhanced in vitro ADCC performance compared to their fucosylated counterparts, with the defucosylated WT antibodies displaying the highest overall ADCC activity, regardless of sialic acid substitution. Moreover, the FcγRIIIA receptor binding by antibodies did not always correspond directly with ADCC result. This study demonstrates that glycoengineering and protein engineering can both promote and inhibit antibody effector functions and represent practical approaches for varying glycan composition and functionalities during antibody development.

The impact of sialylation linkage-type on the pharmacokinetics of recombinant butyrylcholinesterases.

Chinese hamster ovary (CHO) cells typically produce glycoproteins with N-glycans terminating in α-2,3 sialylation. Human cells produce glycoproteins that include α-2,3 and α-2,6 sialic acids. To examine the impact of altering protein sialylation on pharmacokinetic properties, recombinant human butyrylcholinesterase (BChE) was produced in CHO cells by knocking out the α-2,3 sialyltransferase genes followed by overexpression of the α-2,6 sialyltransferase (26BChE) enzyme. The N-glycan composition of 26BChE was compared to BChE with α-2,3 sialylation (23BChE) derived from wild-type CHO cells. Both 23BChE and 26BChE exhibited comparable antennarity distributions with bi-antennary di-sialylated glycans representing the most abundant glycoform. CD-1 mice were intravenously injected with the 23BChE or 26BChE, and residual BChE activities from blood collected at various time points for pharmacokinetic analyses. Although 23BChE contained a slightly lower initial sialylation level compared to 26BChE, the molecule exhibited higher residual activity between 5 and 24 hr postinjection. Pharmacokinetic analyses indicated that 23BChE exhibited an increase in area under the curve and a lower volume of distribution at steady state than that of 26BChE. These findings suggest that the type of sialylation linkage may play a significant role in the pharmacokinetic behavior of a biotherapeutic when tested in in vivo animal models.

Combining Butyrated ManNAc with Glycoengineered CHO Cells Improves EPO Glycan Quality and Production.

Sodium butyrate (NaBu) is not only well-known for enhancing protein production, but also degrades glycan quality. In this study, butyrate supplied by the precursor molecule 1,3,4-O-Bu3 ManNAc is applied to overcome the negative effects of NaBu on glycan quality while simultaneously increasing the productivity of the model recombinant erythropoietin (EPO). The beneficial impact of 1,3,4-O-Bu3 ManNAc on EPO glycan quality, while evident in wild-type CHO cells, is particularly pronounced in glycoengineered CHO cells with stable overexpression of ß-1,4- and ß-1,6-N-acetylglucosaminyltransferases (GnTIV and GnTV) and α-2,6-sialyltransferase (ST6) enzymes responsible for N-glycan antennarity and sialylation. Supplementation of 1,3,4-O-Bu3 ManNAc achieves approximately 30% sialylation enhancement on EPO protein in wild-type CHO cells. Overexpression of GnTIV/GnTV/ST6 in CHO cells increases EPO sialylation about 40%. Combining 1,3,4-O-Bu3 ManNAc treatment in glyocengineered CHO cells promotes EPO sialylation about 75% relative to EPO from wild-type CHO cells. Moreover, a detailed mass spectrometric ESI-LC-MS/MS characterization of glycans at each of the three N-glycosylation sites of EPO showed that the 1st N-site is highly sialylated and either the negative impact of NaBu or the beneficial effect 1,3,4-O-Bu3 ManNAc treatments mainly affects the 2nd and 3rd N-glycan sites of EPO protein. In summary, these results demonstrate 1,3,4-O-Bu3 ManNAc can compensate for the negative effect of NaBu on EPO glycan quality while simultaneously enhancing recombinant protein yields. In this way, a platform that integrates glycoengineering with metabolic supplementation can result in synergistic improvements in both production and glycosylation in CHO cells.

Application of the CRISPR/Cas9 Gene Editing Method for Modulating Antibody Fucosylation in CHO Cells.

Genetic engineering plays an essential role in the development of cell lines for biopharmaceutical manufacturing. Advanced gene editing tools can improve both the productivity of recombinant cell lines as well as the quality of therapeutic antibodies. Antibody glycosylation is a critical quality attribute for therapeutic biologics because the glycan patterns on the antibody fragment crystallizable (Fc) region can alter its clinical efficacy and safety as a therapeutic drug. As an example, recombinant antibodies derived from Chinese hamster ovary (CHO) cells are generally highly fucosylated; the absence of fucose significantly enhances antibody dependent cell-mediated cytotoxicity (ADCC) against cancer cells. This chapter describes a protocol applying clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated protein 9 (Cas9) to disrupt the α-1,6-fucosyltranferase (FUT8) gene and subsequently inhibit α-1,6-fucosylation on antibodies expressed in CHO cells.

Butyrated ManNAc analog improves protein expression in Chinese hamster ovary cells.

The chemical additive sodium butyrate (NaBu) has been applied in cell culture media as a direct and convenient method to increase the protein expression in Chinese hamster ovary (CHO) and other mammalian cells. In this study, we examined an alternative chemical additive, 1,3,4-O-Bu3 ManNAc, for its effect on recombinant protein production in CHO. Supplementation with 1,3,4-O-Bu3 ManNAc for two stable CHO cell lines, expressing human erythropoietin or IgG, enhanced protein expression for both products with negligible impact on cell growth, viability, glucose utilization, and lactate accumulation. In contrast, sodium butyrate treatment resulted in a ∼20% decrease in maximal viable cell density and ∼30% decrease in cell viability at the end of cell cultures compared to untreated or 1,3,4-O-Bu3 ManNAc treated CHO cell lines for both products. While NaBu treatment enhanced product yields more than the 1,3,4-O-Bu3 ManNAc treatment, the NaBu treated cells also exhibited higher levels of caspase 3 positive cells using microscopy analysis. Furthermore, the mRNA levels of four cell apoptosis genes (Cul2, BAK, BAX, and BCL2L11) were up-regulated more in sodium butyrate treated wild-type, erythropoietin, or IgG expressing CHO-K1 cell lines while most of the mRNA levels of apoptosis genes in 1,3,4-O-Bu3 ManNAc treated cell lines remained equal or increased only slightly compared to the levels in untreated CHO cell lines. Finally, lectin blot analysis revealed that the 1,3,4-O-Bu3 ManNAc-treated cells displayed higher relative sialylation levels on recombinant EPO, consistent with the effect of the ManNAc component of this additive, compared to control while NaBu treatment led to lower sialylation levels than control, or 1,3,4-O-Bu3 ManNAc-treatment. These findings demonstrate that 1,3,4-O-Bu3 ManNAc has fewer negative effects on cell cytotoxicity and apoptosis, perhaps as a result of a more deliberate uptake and release of the butyrate compounds, while simultaneously increasing the expression of multiple recombinant proteins, and improving the glycosylation characteristics when applied at comparable molarity levels to NaBu. Thus, 1,3,4-O-Bu3 ManNAc represents a highly promising media additive alternative in cell culture for improving protein yields without sacrificing cell mass and product quality in future bioproduction processes.

Antibody glycoengineering strategies in mammalian cells.

As a key parameter impacting functional and structural heterogeneity, protein glycosylation is a critical quality attribute for antibody biotherapeutic manufacturing. The glycan patterns on recombinant antibodies, particularly on the conserved fragment crystallizable (Fc) region, can have significant effects on an antibody's functional activities including clearance rate, antibody-dependent cellular cytotoxicity (ADCC), complement-dependent cytotoxicity (CDC), and anti-inflammatory activity. In this review, we examined specific glycan attachments (fucosylation, sialylation, galactosylation, high-mannose, and bisecting glycans) and their importance to antibody properties. Next, we summarized the recent and current achievements on controlling antibody glycoforms in Chinese hamster ovary (CHO) and other mammalian cells through multiple strategies including genetic engineering, protein engineering, media modification, and other emerging technologies. Further, the impact of one carbohydrate modification on other glycan structures is also described. Finally, approaches to generate desirable homogenous glycan profiles on antibodies are also detailed. By applying multiple complementary intracellular and extracellular strategies, biotechnologists are well on their ways to precisely tuning antibody glycoforms emerging from bioreactors in the coming decades.

Proline-Rich Chaperones Are Compared Computationally and Experimentally for Their Abilities to Facilitate Recombinant Butyrylcholinesterase Tetramerization in CHO Cells.

Human butyrylcholinesterase (BChE), predominantly tetramers with a residence time of days, offers the potential to scavenge organophosphorus pesticides and chemical warfare agents. Efficient assembly of human BChE into tetramers requires an association with proline-rich peptide chaperones. In this study, the incorporation of different proline-rich peptide chaperones into BChE is investigated computationally and experimentally. First, the authors applied molecular dynamic (MD) simulations to interpret the interactions between proline-rich chaperones with human BChE tetramer domains. The P24 chaperone which contains 24 prolines, promoted the association of BChE tetramer with a 74% simulated helicity of BChE subunits, whereas the control without chaperone and BChE with an 8-proline chaperone (P8) complex exhibited 55.8 and 60.6% predicted helicity, respectively. The interaction of proline-rich chaperones with BChE subunits (B-P) provides a conduit to facilitate the interactions between BChE subunits (B-B) of the complex, which is mainly attributed to hydrophobic interactions and hydrogen-bond binding. Experimental assessment of these two proline-rich chaperones plus a 14-proline chaperone (P14) was performed and confirmed that P24 has superior capability to facilitate recombinant BChE (rBChE) tetramerization with >60% rBChE tetramer in P24-transfected rBChE cells, whereas P14- and P8-transfected rBChE cells had 44 and 33% rBChE tetramer, respectively. The rBChE control had 14% tetramer. Finally, we developed a stable rBChE tetramer expression system in CHO cells by enriching P24 expression in rBChE expressing cells. Overall, our simulations provided a design concept for identifying proline-rich peptides that promote the rBChE tetramerization in CHO cells.

Combinatorial genome and protein engineering yields monoclonal antibodies with hypergalactosylation from CHO cells.

One of the key quality attributes of monoclonal antibodies is the glycan pattern and distribution. Two terminal galactose residues typically represent a small fraction of the total glycans from antibodies. However, antibodies with defined glycosylation properties including enhanced galactosylation have been shown to exhibit altered properties for these important biomedical modalities. In this study, the disruption of two α-2,3 sialyltransferases (ST3GAL4 and ST3GAL6) from Chinese Hamster Ovary (CHO) cells was combined with protein engineering of the Fc region to generate an IgG containing 80% bigalactosylated and fucosylated (G2F) glycoforms. Expression of the same single amino acid mutant (F241A) IgG in CHO cells with a triple gene knockout of fucosyltransferase (FUT8) plus ST3GAL4 and ST3GAL6 lowered the galactosylation glycoprofile to 65% bigalactosylated G2 glycans. However, overexpression of IgGs with four amino acid substitutions recovered the G2 glycoform composition approximately 80%. Combining genome and protein engineering in CHO cells will provide a new antibody production platform that enables biotechnologists to generate glycoforms standards for specific biomedical and biotechnology applications.

SnapShot: N-Glycosylation Processing Pathways across Kingdoms.

Post-translational modification of proteins with carbohydrates shapes their localization and function. This SnapShot presents the core pathways from different organisms that install these complex and highly variable structures.

Glycoengineering of CHO Cells to Improve Product Quality.

Chinese hamster ovary (CHO) cells represent the predominant platform in biopharmaceutical industry for the production of recombinant biotherapeutic proteins, especially glycoproteins. These glycoproteins include oligosaccharide or glycan attachments that represent one of the principal components dictating product quality. Especially important are the N-glycan attachments present on many recombinant glycoproteins of commercial interest. Furthermore, altering the glycan composition can be used to modulate the production quality of a recombinant biotherapeutic from CHO and other mammalian hosts. This review first describes the glycosylation network in mammalian cells and compares the glycosylation patterns between CHO and human cells. Next genetic strategies used in CHO cells to modulate the sialylation patterns through overexpression of sialyltransfereases and other glycosyltransferases are summarized. In addition, other approaches to alter sialylation including manipulation of sialic acid biosynthetic pathways and inhibition of sialidases are described. Finally, this review also covers other strategies such as the glycosylation site insertion and manipulation of glycan heterogeneity to produce desired glycoforms for diverse biotechnology applications.

A novel sugar analog enhances sialic acid production and biotherapeutic sialylation in CHO cells.

A desirable feature of many therapeutic glycoprotein production processes is to maximize the final sialic acid content. In this study, the effect of applying a novel chemical analog of the sialic acid precursor N-acetylmannosamine (ManNAc) on the sialic acid content of cellular proteins and a model recombinant glycoprotein, erythropoietin (EPO), was investigated in CHO-K1 cells. By introducing the 1,3,4-O-Bu3 ManNAc analog at 200-300 µM into cell culture media, the intracellular sialic acid content of EPO-expressing cells increased ∼8-fold over untreated controls while the level of cellular sialylated glycoconjugates increased significantly as well. For example, addition of 200-300 µM 1,3,4-O-Bu3 ManNAc resulted in >40% increase in final sialic acid content of recombinant EPO, while natural ManNAc at ∼100 times higher concentration of 20 mM produced a less profound change in EPO sialylation. Collectively, these results indicate that butyrate-derivatization of ManNAc improves the capacity of cells to incorporate exogenous ManNAc into the sialic acid biosynthetic pathway and thereby increase sialylation of recombinant EPO and other glycoproteins. This study establishes 1,3,4-O-Bu3 ManNAc as a novel chemical supplement to improve glycoprotein quality and sialylation levels at concentrations orders of magnitude lower than alternative approaches. Biotechnol. Bioeng. 2017;114: 1899-1902. © 2017 Wiley Periodicals, Inc.

Integrated Genome and Protein Editing Swaps α-2,6 Sialylation for α-2,3 Sialic Acid on Recombinant Antibodies from CHO.

Immunoglobin G with α-2,6 sialylation has been reported to have an impact on antibody-dependent cellular cytotoxicity and anti-inflammatory efficacy. However, production of antibodies with α-2,6 sialylation from Chinese hamster ovary cells is challenging due to the inaccessibility of sialyltransferases for the heavy chain N-glycan site and the presence of exclusively α-2,3 sialyltransferases. In this study, combining mutations on the Fc regions to allow sialyltransferase accessibility with overexpression of α-2,6 sialyltransferase produced IgG with significant levels of both α-2,6 and α-2,3 sialylation. Therefore, ST3GAL4 and ST3GAL6 genes were disrupted by CRISPR/Cas9 to minimize the α-2,3 sialylation. Sialidase treatment and SNA lectin blot indicated greatly increased α-2,6 sialylation level relative to α-2,3 sialylation for the α-2,3 sialyltransferase knockouts when combined with α-2,6 sialyltransferase overexpression. Indeed, α-2,3 linked sialic acids were not detected on IgG produced from the α-2,3 sialyltransferase knockout-α-2,6 sialyltransferase overexpression pools. Finally, glycoprofiling of IgG with four amino acid substitutions expressed from an α-2,3 sialyltransferase knockout-α-2,6 sialyltransferase stable clone resulted in more than 77% sialylated glycans and more than 62% biantennary disialylated glycans as indicated by both MALDI-TOF and LC-ESI-MS. Engineered antibodies from these modified Chinese hamster ovary cell lines will provide biotechnologists with IgGs containing N-glycans with different structural variations for examining the role of glycosylation on protein performance.

Transparent deoxyribonucleic acid substrate with high mechanical strength for flexible and biocompatible organic resistive memory devices.

Biocompatible deoxyribonucleic acid (DNA), with high mechanical strength, was employed as the substrate for a Ag nanowire (Ag NW) pattern and then used to fabricate flexible resistor-type memory devices. The memory exhibited typical write-once-read-many (WORM)-type memory features with a high ON/OFF ratio (104), long-term retention ability (104 s) and excellent mechanical endurance.

Glycoengineering of Chinese hamster ovary cells for enhanced erythropoietin N-glycan branching and sialylation.

Sialic acid, a terminal residue on complex N-glycans, and branching or antennarity can play key roles in both the biological activity and circulatory lifetime of recombinant glycoproteins of therapeutic interest. In order to examine the impact of glycosyltransferase expression on the N-glycosylation of recombinant erythropoietin (rEPO), a human α2,6-sialyltransferase (ST6Gal1) was expressed in Chinese hamster ovary (CHO-K1) cells. Sialylation increased on both EPO and CHO cellular proteins as observed by SNA lectin analysis, and HPLC profiling revealed that the sialic acid content of total glycans on EPO increased by 26%. The increase in sialic acid content was further verified by detailed profiling of the N-glycan structures using mass spectra (MS) analysis. In order to enhance antennarity/branching, UDP-N-acetylglucosamine: α-1,3-D-mannoside ß1,4-N-acetylglucosaminyltransferase (GnTIV/Mgat4) and UDP-N-acetylglucosamine:α-1,6-D-mannoside ß1,6-N-acetylglucosaminyltransferase (GnTV/Mgat5), was incorporated into CHO-K1 together with ST6Gal1. Tri- and tetraantennary N-glycans represented approximately 92% of the total N-glycans on the resulting EPO as measured using MS analysis. Furthermore, sialic acid content of rEPO from these engineered cells was increased ∼45% higher with tetra-sialylation accounting for ∼10% of total sugar chains compared to ∼3% for the wild-type parental CHO-K1. In this way, coordinated overexpression of these three glycosyltransferases for the first time in model CHO-K1 cell lines provides a mean for enhancing both N-glycan branching complexity and sialylation with opportunities to generate tailored complex N-glycan structures on therapeutic glycoproteins in the future.

Assessment of the coordinated role of ST3GAL3, ST3GAL4 and ST3GAL6 on the α2,3 sialylation linkage of mammalian glycoproteins.

In this research, we examined which genes are involved in N-linked sialylation in Chinese Hamster Ovary (CHO) cells using siRNA knockdown approaches. Three genes from the sialyltransferase family (ST3GAL3, ST3GAL4 and ST3GAL6) were chosen as knockdown targets with siRNA applied to reduce their expression. Single, double and triple gene knockdowns were investigated, and the reduction levels of sialylation on the total cell lysate were monitored by enzyme-linked lectin absorption assays (ELLA) and sialic acid quantification with high performance liquid chromatography (HPLC). All transfection groups showed effective reduction in 2,3-linked sialylation whereas the trend of reduction levels of triple siRNA transfection outweighed both the dual siRNA groups and single siRNA transfection groups. Next, this transfection approach was applied to CHO cells producing erythropoietin (EPO). Quantification of EPO sialylation showed similar result to total cell lysate except that the ST3GAL4 siRNA transfection exhibited the largest reduction according to the HPLC analysis as compared with other single siRNA transfections. Finally, the N-glycan released from the EPO transfected with ST3GAL4 siRNA showed a prominent reduction in sialyation level among the single siRNA transfections. From these experiments, we concluded that each of these three genes were involved in N-linked sialylation and ST3GAL4 may play the critical role in glycoprotein sialylation of recombinant proteins such as EPO.

CHO microRNA engineering is growing up: recent successes and future challenges.

microRNAs with their ability to regulate complex pathways that control cellular behavior and phenotype have been proposed as potential targets for cell engineering in the context of optimization of biopharmaceutical production cell lines, specifically of Chinese Hamster Ovary cells. However, until recently, research was limited by a lack of genomic sequence information on this industrially important cell line. With the publication of the genomic sequence and other relevant data sets for CHO cells since 2011, the doors have been opened for an improved understanding of CHO cell physiology and for the development of the necessary tools for novel engineering strategies. In the present review we discuss both knowledge on the regulatory mechanisms of microRNAs obtained from other biological models and proof of concepts already performed on CHO cells, thus providing an outlook of potential applications of microRNA engineering in production cell lines.