On the effect of transient expression of mutated elF2α and elF4E eukaryotic translation initiation factors on reporter gene expression in mammalian cells upon cold-shock

There are a growing number of reports on the beneficial effects of subphysiological temperature in vitro culturing (27–35°C) of mammalian cells on recombinant protein yield. However, this effect is not conserved across cell lines and target products, and our understanding of the molecular mechanism(s) responsible for increased recombinant protein yield upon reduced temperature culturing of mammalian cells is poor. What is known is that mammalian cells respond to cold-shock by attenuating global cap-dependent translation. Here, we have investigated the hypothesis that the cap-dependent attenuation of mRNA translation upon cold-stress of in vitro-cultured mammalian cells can be prevented, or at least alleviated, by overexpressing mutant translation initiation factors in Chinese hamster ovary and HeLa cells. We have shown that the transient coexpression of either an eIF2αSer⁵¹→Ala⁵¹ mutant or an eIF4ESer²⁰⁹→Glu²⁰⁹ mutant with firefly luciferase affects luciferase expression levels in a cell line and temperature dependent manner. Further, regardless of the coexpression of initiation factors, transient reporter gene expression was enhanced at subphysiological temperatures (<37°C), suggesting that reduced temperature cultivation can be used to improve the yield of recombinant protein during transient expression. The implications of these results upon cell engineering strategies involving manipulation of the translational apparatus for the enhancement of recombinant protein synthesis upon cold-shock are discussed. Joint first authors who contributed equally to this work     

Metabolic Rates,Growth Phase,and mRNA Levels Influence Cell-Specific Antibody Production Levels from In Vitro-Cultured Mammalian Cells at Sub-Physiological Temperatures

Previous work has shown that recombinant protein yield can be improved from in vitro-cultured mammalian cells by culturing at sub-physiological temperatures, although this effect is cell line and product dependent. The mechanism(s) by which low temperature leads to enhanced product yield are currently unknown; however, recent reports suggest that increased mRNA levels at sub-physiological temperatures may be largely responsible for this. Here, we have investigated whether low-temperature cultivation of cell lines selected for antibody production at 37°C leads to changes in heavy- and light-chain mRNA levels and if this is reflected in antibody yields. Low-temperature in vitro culturing resulted in reduced viable cell concentration, prolonged cell viability, a reduction in metabolite consumption and production, cell cycle arrest in both CHO and NS0 cells, and changes in the levels of heavy- and light-chain mRNA. Despite increases in the level of heavy- and light-chain mRNA upon culturing at 32°C in our model CHO cell line, this did not result in increased total product yield; however, changes in cell-specific yields were observed that reflected the metabolic rate of glucose utilization and changes in mRNA levels.     

Endoplasmic reticulum‐directed recombinant mRNA displays subcellular localization equal to endogenous mRNA during transient expression in CHO cells

When expressing pharmaceutical recombinant proteins in mammalian cells, the protein is commonly directed through the secretory pathway, in a signal peptide‐dependent manner, to acquire specific post‐translational modifications and to facilitate secretion into the culture medium. One key premise for this is the direction of the mRNA encoding the recombinant protein to the surface of the endoplasmic reticulum (ER) for subsequent protein translocation into the secretory pathway. To evaluate the efficiency of this process in Chinese hamster ovary (CHO) cells, the subcellular localization of recombinant mRNA encoding the therapeutic proteins, erythropoietin (EPO) and Rituximab, was determined. The results show that ER‐directed recombinant mRNAs exhibited an efficient recruitment to the ER when compared to an endogenous ER‐directed mRNA, with no cytoplasmic translation of ER‐directed recombinant proteins observed. These observations indicate that the recombinant mRNA, encoding ER‐directed proteins, follows the same distribution pattern as endogenous mRNA directed towards the ER. Furthermore, the previous established fractionation method proves to be an efficient tool to study not only recombinant mRNA localization, but also recombinant protein trafficking between the ER and cytosol in CHO cells.     

Effect of temperature on recombinant protein expression in Semliki Forest virus infected mammalian cell lines growing in serum- free suspension cultures

The firefly luciferase gene was introduced into the Semliki Forest virus (SFV) vector and high titer recombinant SFV particles generated. The broad host range of SFV allowed efficient infection and high level expression of four mammalian cell lines growing in serum-free suspension cultures. The incubation temperature had dramatic effects on the level and duration of recombinant protein expression. For example, the luciferase activity was significantly higher in the rodent BHK and CHO cell lines incubated at 33 °C compared to 37 °C when harvested 19 h post-infection. At 33 °C the specific expression levels increased 10–20 fold during prolongation of the post-infection time up to 50 h. In contrast, a significant decrease in luciferase activity was observed from 26 h post-infection for cell cultures incubated at 37 °C. Only a slight temperature effect on luciferase expression was seen in the human cell line HEK293 and no effect was observed for the subclone293(EBNA). This revised version was published online in August 2006 with corrections to the Cover Date.     

Post-transcriptional regulation in higher eukaryotes: the role of the reporter gene in controlling expression

We have investigated whether reporter genes influence cytoplasmic regulation of gene expression in tobacco and Chinese hamster ovary (CHO) cells. Two genes, uidA encoding beta-glucuronidase (GUS) from Escherichia coli and Luc, encoding firefly luciferase (LUC), were used to analyze the ability of a cap, polyadenylated tail, and the 5'- and 3'-untranslated regions (UTR) from tobacco mosaic virus (TMV) to regulate expression. The regulation associated with the 5' cap structure and the TMV 5'-UTR, both of which enhance translational efficiency, was reporter gene-independent. The poly(A) tail and the TMV 3'-UTR, which is functionally equivalent to a poly(A) tail, increase translational efficiency as well as mRNA stability. The regulation associated with these 3' ends was highly reporter gene-dependent; their effect on GUS expression was almost an order of magnitude greater than that on LUC expression. In tobacco, the tenfold reporter gene effect on poly(A) tail or TMV 3'-UTR function could not be explained by a differential impact on mRNA stability; GUS and LUC mRNA half-life increased only twofold when either the poly(A) tail or TMV 3'-UTR was present. In CHO cells, however, GUS mRNA was stabilized to a greater extent by a poly(A) tail or the TMV 3'-UTR than was LUC mRNA.     

Evidence for a nuclease in Saccharomyces cerevisiae that affects the cell-free translation of natural messenger RNA.

A postpolysomal extract of $\text{Saccharomyces}\text{cerevisiae}$, treated with micrococcal nuclease to remove endogenous mRNAs, translates exogenous natural and synthetic mRNA templates actively and accurately at 20°C. When the temperature of incubation is 30°C or higher, protein synthesis with yeast poly(A)⁺ mRNA is markedly reduced, but synthesis of polyphenyl-alanine with poly (U) is only slightly affected. The protein synthesizing activity of the extract is decreased 50% in 30 minutes at 37°C, while the ability of yeast mRNA to template for protein synthesis is decreased 50% in 5 to 7 minutes when it is incubated with the postpolysomal fraction at 37°C. The release of radioactivity from isotopically-labeled yeast mRNA, into the acid-soluble form, is also much greater at 37°C than at 20°C. Thus, at the elevated temperatures, the loss of mRNA templating activity and RNA hydrolysis occur more rapidly than the loss of activity of the translational apparatus. The evidence suggests that the failure of the extract to catalyze translation at 30°C or higher, as compared to 20°C, is due to a temperature-stimulated nuclease that degrades mRNA.     

Enhancement of productivity of recombinant α-amidating enzyme by low temperature culture

We have produced a recombinant C-terminal α-amidating enzyme (799BglIIα-AE) derived from Xenopus laevis by culturing a CHO cell line named 3μ-1S. Recently, we demonstrated that culturing 3μ-1S cells at a temperature below 37 °C led to the following phenomena: inhibited cell growth with high viability, enhanced cellular productivity (maximally at 32 °C), and suppressed medium consumption and release of impurities from the cells. Therefore, it is suggested that the 799BglIIα-AE production will be increased by culturing a sufficient number of the cells at a low temperature (especially at 32 °C). To assess this effect on batch and perfusion cultures, the culture temperature was shifted from 37 to 32 °C in the mid-exponential phase in the case of batch culture and from 37 to 34 °C when the cell density became high enough in the case of perfusion culture. Application of the low temperature culture to batch and perfusion cultures was effective in comparison with the culture at 37 °C: the productivity per medium and the productivity per time were increased severalfold with enhanced cellular productivity at a low culture temperature. The low temperature culture also increased the relative content of 799BglIIα-AE in the supernatant and reduced the glucose consumption. The method presented here would contribute to production of bioactive proteins using other recombinant cell lines. This revised version was published online in August 2006 with corrections to the Cover Date.     

HSP 70 gene expression in Trypanosoma cruzi is regulated at different levels

The level of HSP 70 mRNA is altered in Trypanosoma cruzi cells incubated at supra-optimal temperatures: the total amount of this RNA per cell is increased at 37°C, and slightly decreased at 40°C relative to its level at 29°C. However, its amount is greater in the polysomes at either temperature. The relative increase of this RNA is larger in the polysomes fraction than it is in the total RNA. In addition the level of HSP 70 protein in heat-shocked cells is greater than would be expected from the recruitment of HSP 70 mRNA in the polysomal fraction. Taken together the data are interpreted as indicating that at 37°C and 40°C the HSP 70 gene regulation in T. cruzi involves both the selective accumulation of the HSP 70 mRNA in the polysomes and its preferential translation. At 37°C, in addition, an increase in the total amount of this template is observed in the cells.     

Development and optimization of a cell‐based assay for the selection of synthetic compounds that potentiate bone morphogenetic protein‐2 activity

The requirement of large amounts of the recombinant human bone morphogenetic protein‐2 (BMP‐2) produces a huge translational barrier for its routine clinical use due to high cost. This leads to an urgent need to develop alternative methods to lower costs and/or increase efficacies for using BMP‐2. In this study, we describe the development and optimization of a cell‐based assay that is sensitive, reproducible, and reliable in identifying reagents that potentiate the effects of BMP‐2 in inducing transdifferentiation of C2C12 myoblasts into the osteoblastic phenotype. The assay is based on a BMP‐responsive Smad1‐driven luciferase reporter gene. LIM mineralization protein‐1 (LMP‐1) is a novel intracellular LIM domain protein that has been shown by our group to enhance cellular responsiveness to BMP‐2. Our previous report elucidated that the binding of LMP‐1 with the WW2 domain in Smad ubiquitin regulatory factor‐1 (Smurf1) rescues the osteogenic Smads from degradation. Here, using the optimized cell‐based assay, we first evaluated the activity of the recombinantly prepared proteins, LMP‐1, and its mutant (LMP‐1ΔSmurf1) that lacks the Smurf1‐WW2 domain‐binding motif. Both the wild type and the mutant proteins were engineered to contain an 11‐amino acid HIV‐TAT protein derived membrane transduction domain to aid the cellular delivery of recombinant proteins. The cell‐based reporter assay confirmed that LMP‐1 potentiates the BMP‐induced stimulation of C2C12 cells towards the osteoblastic phenotype. The potentiating effect of LMP‐1 was significantly reduced when a specific‐motif known to interact with Smurf1 was mutated. We validated the results obtained in the reporter assay by also monitoring the expression of mRNA for osteocalcin and alkaline phosphatase (ALP) which is widely accepted osteoblast differentiation marker genes. Finally, we provide further confirmation of our results by measuring the activity of alkaline phosphatase in support of the accuracy and reliability of our cell‐based assay. Direct delivery of synthesized protein can be limited by high cost, instability or inadequate post‐translational modifications. Thus, there would be a clear benefit for a low cost, cell penetrable chemical compound. We successfully used our gene expression‐based assay to choose an active compound from a select group of compounds that were identified by computational screenings as the most likely candidates for mimicking the function of LMP‐1. Among them, we selected SVAK‐3, a compound that showed a dose‐dependent potentiation of BMP‐2 activity in inducing osteoblastic differentiation of C2C12 cells. We show that either the full length LMP‐1 protein or its potential mimetic compound consistently exhibit similar potentiation of BMP‐2 activity even when multiple markers of the osteoblastic phenotype were parallely monitored. Published in 2009 by John Wiley & Sons, Ltd.     

Control of translation by the 5'- and 3'-terminal regions of the dengue virus genome

The genomic RNAs of flaviviruses such as dengue virus (DEN) have a 5' m7GpppN cap like those of cellular mRNAs but lack a 3' poly(A) tail. We have studied the contributions to translational expression of 5'- and 3'-terminal regions of the DEN serotype 2 genome by using luciferase reporter mRNAs transfected into Vero cells. DCLD RNA contained the entire DEN 5' and 3' untranslated regions (UTRs), as well as the first 36 codons of the capsid coding region fused to the luciferase reporter gene. Capped DCLD RNA was as efficiently translated in Vero cells as capped GLGpA RNA, a reporter with UTRs from the highly expressed alpha-globin mRNA and a 72-residue poly(A) tail. Analogous reporter RNAs with regulatory sequences from West Nile and Sindbis viruses were also strongly expressed. Although capped DCLD RNA was expressed much more efficiently than its uncapped form, uncapped DCLD RNA was translated 6 to 12 times more efficiently than uncapped RNAs with UTRs from globin mRNA. The 5' cap and DEN 3' UTR were the main sources of the translational efficiency of DCLD RNA, and they acted synergistically in enhancing translation. The DEN 3' UTR increased mRNA stability, although this effect was considerably weaker than the enhancement of translational efficiency. The DEN 3' UTR thus has translational regulatory properties similar to those of a poly(A) tail. Its translation-enhancing effect was observed for RNAs with globin or DEN 5' sequences, indicating no codependency between viral 5' and 3' sequences. Deletion studies showed that translational enhancement provided by the DEN 3' UTR is attributable to the cumulative contributions of several conserved elements, as well as a nonconserved domain adjacent to the stop codon. One of the conserved elements was the conserved sequence (CS) CS1 that is complementary to cCS1 present in the 5' end of the DEN polyprotein open reading frame. Complementarity between CS1 and cCS1 was not required for efficient translation.     

Engineering mRNA translation initiation to enhance transient gene expression in chinese hamster ovary cells

To increase transient expression of recombinant proteins in Chinese hamster ovary cells, we have engineered their protein synthetic capacity by directed manipulation of mRNA translation initiation. To control this process we constructed a nonphosphorylatable Ser(51)Ala site-directed mutant of eIF2alpha, a subunit of the trimeric eIF2 complex that is implicated in regulation of the global rate of mRNA translation initiation in eukaryotic cells. Phosphorylation of eIF2alpha by protein kinases inhibits eIF2 activity and is known to increase as cells perceive a range of stress conditions. Using single- and dual-gene plasmids introduced into CHO cells by electroporation, we found that transient expression of the eIF2alpha Ser(51)Ala mutant with firefly luciferase resulted in a 3-fold increase in reporter activity, relative to cells transfected with reporter only. This effect was maintained in transfected cells for at least 48 h after transfection. Expression of the wild-type eIF2alpha protein had no such effect. Elevated luciferase activity was associated with a reduction in the level of eIF2alpha phosphorylation in cells transfected with the mutant eIF2alpha construct. Transfection of CHO cells with the luciferase-only construct resulted in a marked decrease in the global rate of protein synthesis in the whole cell population 6 h post-transfection. However, expression of the mutant Ser(51)Ala or wild-type eIF2alpha proteins restored the rate of protein synthesis in transfected cells to a level equivalent to or exceeding that of control cells. Associated with this, entry of plasmid DNA into cells during electroporation was visualized by confocal microscopy using a rhodamine-labeled plasmid construct expressing green fluorescent protein. Six hours after transfection, plasmid DNA was present in all cells, albeit to a variable extent. These data suggest that entry of naked DNA into the cell itself functions to inhibit protein synthesis by signaling mechanisms affecting control of mRNA translation by eIF2. This work therefore forms the basis of a rational strategy to generically up-regulate transient expression of recombinant proteins by simultaneous host cell engineering.     

Cell Culture Evaluation of the Semliki Forest Virus Expression System As a Novel Approach for Antigen Delivery and Expression in Fish

Heterologous gene expression by Semliki Forest virus (SFV) expression vectors was investigated in fish cell culture. Experiments performed using an infectious strain of SFV, replication-defective SFV particles, and recombinant SFV RNA constructs encoding the Escherchia coli LacZ or firefly luciferase reporter genes indicated that levels of SFV-mediated expression in fish cells were dependent on cell type and temperature. Maximal expression levels were observed in the two salmonid-derived cell lines CHSE-214 and F95/9 at 25°C and 20°C. As the temperature was lowered to 15°C or below, levels of reporter gene expression were reduced up to 1000-fold, indicating that the SFV replication complex functioned inefficiently at low temperatures. The ability of SFV expression systems to function in fish cells was further investigated by analyzing the expression of the protective VP2 antigen of infectious pancreatic necrosis virus (IPNV) from the various constructs, including a novel DNA-based SFV plasmid. The VP2 protein produced in CHSE-214 and F95/9 cells transfected or infected with the recombinant SFV-IPNV VP2 constructs appeared to be synthesized in an antigenically correct form, as evidenced by the ability to react with several conformation-dependent IPNV-specific monoclonal antibodies. Whether the temperature-restricted replication and expression displayed by SFV-based constructs in fish cell culture also occurs in vivo remains to be determined. Received January 29; accepted June 29, 1999.