Conserved microRNAs in Chinese hamster ovary cell lines.

MicroRNAs (miRNAs), a class of short (20-24 nt) non-coding RNAs that direct post-transcriptional repression of messenger RNAs, increasingly have been shown to play a key role in regulating cellular physiology. We investigated the prevalence of miRNAs in Chinese hamster ovary (CHO) cells by high-throughput sequencing. Six cDNA libraries of small RNAs from four CHO cell lines were constructed and sequenced by Illumina sequencing. Three hundred fifty distinct miRNA and miRNA* sequences were identified through homology with other species, including mouse, rat, and human. While the majority of the identified miRNAs appear to be expressed ubiquitously, many miRNAs were found to have a wide range of expression levels between cell lines. The identification of these miRNAs will facilitate investigations of their contribution to the hyperproductivity trait.

Co-expression of Skp and FkpA chaperones improves cell viability and alters the global expression of stress response genes during scFvD1.3 production.

BACKGROUND: The overexpression of scFv antibody fragments in the periplasmic space of Escherichia coli frequently results in extensive protein misfolding and loss of cell viability. Although protein folding factors such as Skp and FkpA are often exploited to restore the solubility and functionality of recombinant protein products, their exact impact on cellular metabolism during periplasmic antibody fragment expression is not clearly understood. In this study, we expressed the scFvD1.3 antibody fragment in E. coli BL21 and evaluated the overall physiological and global gene expression changes upon Skp or FkpA co-expression. RESULTS: The periplasmic expression of scFvD1.3 led to a rapid accumulation of insoluble scFvD1.3 proteins and a decrease in cell viability. The co-expression of Skp and FkpA improved scFvD1.3 solubility and cell viability in a dosage-dependent manner. Through mutagenesis experiments, it was found that only the chaperone activity of FkpA, not the peptidyl-prolyl isomerase (PPIase) activity, is required for the improvement in cell viability. Global gene expression analysis of the scFvD1.3 cells over the chaperone-expressing cells showed a clear up-regulation of genes involved in heat-shock and misfolded protein stress responses. These included genes of the major HSP70 DnaK chaperone family and key proteases belonging to the Clp and Lon protease systems. Other metabolic gene expression trends include: (1) the differential regulation of several energy metabolic genes, (2) down-regulation of the central metabolic TCA cycle and transport genes, and (3) up-regulation of ribosomal genes. CONCLUSIONS: The simultaneous activation of multiple stress related and other metabolic genes may constitute the stress response to protein misfolding in the scFvD1.3 cells. These gene expression information could prove to be valuable for the selection and construction of reporter contructs to monitor the misfolded protein stress response during antibody fragment production.

Quality assessment of cross-species hybridization of CHO transcriptome on a mouse DNA oligo microarray.

DNA microarray technology has been widely utilized for species with extensive genome sequence information available. Given the limited genomic information pertaining to Chinese hamster ovary (CHO) cell line, cross-species hybridization using mouse microarrays provides a viable alternative. In this study, the utility of mouse Affymetrix microarrays for transcriptome profiling in CHO cells was assessed by hybridizing identical sets of cRNA samples from CHO cells on both mouse and CHO Affymetrix microarrays. Expression level measured by probe sets for orthologous transcripts on the two microarrays was compared. Only a fraction of the orthologous probes which detected expression calls in same species hybridization were similarly called present in cross species hybridization. In further analysis at the 25-mer probe level, it was revealed that specific hybridization signals were detectable by the subset of mouse probes that have a high degree of homology to the corresponding CHO sequences. The feasibility of cross species hybridization for quantifying the extent of differential expression was assessed by comparing transcript levels of CHO cells cultivated with and without sodium butyrate. While same species hybridization gave consistent degree of differential expression calls in replicated runs, a much inferior ability in quantifying differential expression was seen with cross species hybridization. Our results demonstrate that through detailed analysis of homology at the probe pair level, a subset of probes on existing mouse Affymetrix oligo-array can be used successfully for transcriptome profiling of CHO cells.

Inactivating FruR global regulator in plasmid-bearing Escherichia coli alters metabolic gene expression and improves growth rate.

The introduction of plasmids into Escherichia coli is known to impose a metabolic burden, which diminishes the growth rate. This effect could arise from perturbation of the central metabolic pathways, which supply precursors and energy for macromolecule synthesis. We knocked out a global regulator of central metabolism, FruR (also called Cra), to assess its phenotypic effect in E. coli carrying plasmids. During bioreactor runs, a higher specific growth rate of 0.91h(-1) was observed for the plasmid-bearing fruR knockout (P+ fruR) cells compared to its parental plasmid-bearing wildtype (P+ WT) cells (0.75h(-1)), while both the plasmid-free cells displayed similar growth rates (1.0h(-1), respectively). To investigate gene expression changes possibly related to the growth rate recovery, quantitative reverse transcriptase PCR and 2DE proteomic studies were performed. In P+ fruR cells, expression of enzymes involved in sugar catabolism, glycolysis and transcription/translation processes were upregulated, while those related to gluconeogenesis, tricarboxylic acid cycle and stress response were downregulated. Our findings demonstrate that the inactivation of FruR global regulator in recombinant E. coli alters metabolic gene expression and significantly reduces growth retardation from the burden of maintaining a plasmid. This study represents the first attempt to explore the role of a global regulatory gene on plasmid metabolic burden.

Comparative transcriptional analysis of mouse hybridoma and recombinant Chinese hamster ovary cells undergoing butyrate treatment.

DNA microarray based transcriptome analysis has become widely used in biomedical research; however, the lack of DNA sequence information available for Chinese hamster ovary (CHO) cells has hampered the application of microarrays for this cell line widely used for recombinant therapeutic protein production. We have constructed an expressed sequence tag (EST) based CHO DNA microarray and employed it for comparative transcriptome analysis of CHO cells and mouse hybridoma cells treated with sodium butyrate. Cross-species hybridization of CHO transcripts to mouse DNA microarrays was also performed to assess the utility of cross-species microarray. The average identity among probe sequences present on both the CHO and mouse microarray was 89.6%. Although cross-species hybridization yielded non-contradicting results when compared with the same-species arrays, decreased sensitivity was observed and resulted in fewer differentially expressed genes being confidently identified. The comparatively small number of genes probed using the CHO microarray and the low number of genes identified as differentially expressed in the cross-species hybridization limited physiological interpretation of the response of CHO cells to sodium butyrate treatment. Nevertheless, when all results are combined, mouse hybridoma and CHO cells can be seen to respond similarly to butyrate treatment, affecting histone modification, chaperones, lipid metabolism, and protein processing. To further develop the utility of microarray technology in cell culture process development, an expansion of current CHO cell sequencing efforts to increase the coverage of genes on available microarrays is warranted.

Hcc-2, a novel mammalian ER thioredoxin that is differentially expressed in hepatocellular carcinoma.

Hepatocellular carcinoma (HCC) is the most common primary cancer of the liver. Thus there is great interest to identify novel HCC diagnostic markers for early detection of the disease and tumour specific associated proteins as potential therapeutic targets in the treatment of HCC. Currently, we are screening for early biomarkers as well as studying the development of HCC by identifying the differentially expressed proteins of HCC tissues during different stages of disease progression. We have isolated, by reverse transcriptase and polymerase chain reaction (RT-PCR), a 1741bp cDNA encoding a protein that is differentially expressed in HCC. This novel protein was initially identified by proteome analysis and we designate it as Hcc-2. The protein is upregulated in poorly-differentiated HCC but unchanged in well-differentiated HCC. The full-length transcript encodes a protein of 363 amino acids that has three thioredoxin (Trx) (CGHC) domains and an ER retention signal motif (KDEL). Fluorescence GFP tagging to this protein confirmed that it is localized predominantly to the cytoplasm when expressed in mammalian cells. Protein alignment analysis shows that it is a variant of the TXNDC5 gene, and the human variants found in Genbank all show close similarity in protein sequence. Functionally, it exhibits the anticipated reductase activity in the insulin disulfide reduction assay, but its other biological role in cell function remains to be elucidated. This work demonstrates that an integrated proteomics and genomics approach can be a very powerful means of discovering potential diagnostic and therapeutic protein targets for cancer therapy.

Transcriptome and proteome profiling to understanding the biology of high productivity CHO cells.

A combined transcriptome and proteome analysis was carried out to identify key genes and proteins differentially expressed in Chinese hamster ovary (CHO) cells producing high and low levels of dhfr-GFP fusion protein. Comparison of transcript levels was performed using a proprietary 15K CHO cDNA microarray chip, whereas proteomic analysis was performed using iTRAQ quantitative protein profiling technique. Microarray analysis revealed 77 differentially expressed genes, with 53 genes upregulated and 24 genes downregulated. Proteomic analysis gave 75 and 80 proteins for the midexponential and stationary phase, respectively. Although there was a general lack of correlation between mRNA levels and quantitated protein abundance, results from both datasets concurred on groups of proteins/genes based on functional categorization. A number of genes (20%) and proteins (45 and 23%) were involved in processes related to protein biosynthesis. We also identified three genes/proteins involved in chromatin modification. Enzymes responsible for opening up chromatin, Hmgn3 and Hmgb1, were upregulated whereas enzymes that condense chromatin, histone H1.2, were downregulated. Genes and proteins that promote cell growth (Igfbp4, Ptma, S100a6, and Lgals3) were downregulated, whereas those that deter cell growth (Ccng2, Gsg2, and S100a11) were upregulated. Other main groups of genes and proteins include carbohydrate metabolism, signal transduction, and transport. Our findings show that an integrated genomic and proteomics approach can be effectively utilized to monitor transcriptional and posttranscriptional events of mammalian cells in culture.

Inhibition of human cytomegalovirus replication by overexpression of CREB1.

Expression of the human cytomegalovirus (HCMV) major immediate-early (MIE) genes is regulated by a strong enhancer-containing promoter with multiple binding sites for various transcription factors, including cyclic AMP response element binding protein 1 (CREB1). Here we show that overexpression of CREB1 potently blocked MIE transcription and HCMV replication. Surprisingly, CREB1 still exhibited strong inhibition of the MIE promoter when all five CREB binding sites within the enhancer were mutated, suggesting that CREB1 regulated the MIE gene expression indirectly. Promoter deletion analysis and site-directed mutagenesis identified the region between -130 and -50 upstream of the transcription start site of the MIE gene as the "CREB1 responsive region". Mutations of SP1/3 and NF-κB binding sites within this region interrupted the inhibitory effect induced by CREB1 overexpression. Our findings suggest that overexpression of CREB1 can cause repression of HCMV replication and may contribute to the development of new anti-HCMV strategies.

Identification and expression analysis of miRNAs during batch culture of HEK-293 cells.

MicroRNAs (miRNAs) are small non-coding RNAs of about 20-24 nucleotides in length. They regulate gene expression negatively and have been implicated in a wide variety of biological processes. To identify potential miRNAs that may influence the growth and proliferation of mammalian cells cultured in bioreactors, we applied miRNA microarray expression profiling technology to batch cultures of HEK293 cells in protein free media. In our study, we identified miRNAs that were differentially expressed during the exponential and stationary phases, 13 of these showed distinct up regulation trends while 1 exhibited down regulation. These miRNAs have been implicated in cellular differentiation, growth arrest and apoptosis. Specifically, miR-16 and let-7b are potentially useful in the enhancement of bioreactor cell cultures.

Developing genomic platforms for Chinese hamster ovary cells.

Chinese hamster ovary (CHO) cells are widely used in recombinant protein production, yet despite their importance in bioprocessing, few genomic resources have been developed for this cell line. Over the past several years, we have made considerable progress in the development of genomic tools for CHO. Using Sanger-based sequencing technology, we have accrued a sequence repertoire of more than 68,000 expressed sequence tags (ESTs), representing more than 28,000 unique CHO transcripts. Using closely related species, we have functionally annotated this sequence set and have currently achieved significant representation in a number of functional classes, including some closely tied to recombinant protein production. This sequence repository has been used to design custom CHO Affymetrix arrays for transcriptome analysis. Illumina Solexa deep sequencing technology was also applied to study the CHO cell transcriptome and survey the identity and expression of small RNAs. These applications demonstrate the utility of genomic tools, and illustrate the applicability of emerging next-generation sequencing technologies.

Generation of high-level stable transgene expressing human embryonic stem cell lines using Chinese hamster elongation factor-1 alpha promoter system.

The utilization of human embryonic stem cells (hESC) in regenerative medicine largely depends on the development of technologies that will allow efficient genetic manipulation of the cells in vitro. Although a few studies have described the transfection of hESC for generation of reporter lines stably expressing specific transgenes driven by different promoters, the optimal choice of promoter system for driving transgene in hESC has yet to be elucidated. We show for the first time that Chinese hamster elongation factor-1 alpha (CHEF1) promoter robustly drove reporter gene expression higher than the human elongation factor 1 alpha (hEF1 alpha), other constitutive Chinese hamster promoters, human cytomegalovirus (CMV) immediate early enhancer/promoter and SV40 promoters in hESC by quantitative analysis. We also successfully generated stably transfected hESC lines using this CHEF1 promoter system and demonstrated that they continued to express enhanced green fluorescent protein (EGFP) during prolonged undifferentiated proliferation, in differentiated embryoid bodies (EBs), and in teratomas without transgene silencing. By immunofluorescence staining and D ow cytometry analysis, the pluripotent markers, OCT-4, SSEA-4, and TRA-1-60, continued to be expressed in undifferentiated CHEF1-EGFP expressing hESC lines. When the stably transfected hESC were directed to differentiate into neural precursors in vitro, high-level EGFP expression was maintained and co-expression of neural markers, Nestin, and beta-tubulin III was observed. The morphology, karyotype, and telomerase activity of CHEF1-EGFP expressing hESC were normal after >50 continuous passages, and the cells retained the ability to differentiate into derivatives of the three germ layers in vitro as confirmed by RT-PCR analysis and immunocytochemical staining and in vivo teratoma formation. Therefore, stable CHEF1-EGFP hESC lines retained the capability for self-renewal and pluripotency. The novel CHEF1 promoter system described here enables high-level transgene expression in the stably transfected hESC. It may have signi, cant implication for uses in bioprocess development and future development of gene-modified hESC in tissue regeneration and transplantation applications.

Specific detection of residual CHO host cell DNA by real-time PCR.

Chinese hamster ovary cells have been widely used to manufacture recombinant proteins for human therapeutic use. A sensitive quantitative real-time polymerase chain reaction assay for the detection of residual Chinese hamster (Cricetulus griseus) DNA is presented in this paper. The assay is reasonably affordable and can be adapted for high-throughput screening using 96-well format. Real-time PCR primers were designed to amplify a 150bp region of a genomic fragment from hamster DNA. The specificity of the probe was evaluated in real-time PCR reactions using genomic DNA from mouse fibroblast, human kidney and hamster ovary cell lines as template. Sensitivity of real-time PCR was compared on genomic DNA from hamster cell line CHO DG44. These primers can be used in real-time PCR reactions to detect presence of contaminating hamster DNA in purified protein samples down to sensitivity of 300fg genomic DNA.

Transcriptional profiling of batch and fed-batch protein-free 293-HEK cultures.

Dynamic nutrient feeding to control glutamine at low levels in protein-free fed-batch cultures of 293-human embryonic kidney (HEK) cells achieved cell concentrations of 6 x 10(6) cells/ml. This represented a 4-fold improvement in cell concentration compared to batch cultures. Reduction in glutamine and glucose consumption, as well as lactate and ammonia production, were also observed in these fed-batch cultures. High virus production titers of 3 x 10(11) pfu/ml were achieved in fed-batch cultures which were 10,000-fold higher than batch cultures. An investigation of the transcriptional regulation of the metabolic changes associated with the batch and the low-glutamine fed-batch cultures using DNA microarray was conducted. This analysis provides better understanding of the transcriptional regulatory mechanism resulting in the observed physiological changes. Transcriptional profiling of cells from the mid-exponential, late exponential and stationary phases of both the batch and fed-batch were undertaken using an 18,000 element human chip. Transcriptional profiles were ontologically classified to provide a global view of the genetic changes. Furthermore, a pathway-oriented analysis focusing on cellular metabolism was conducted to reveal the dynamic regulation of genes related to amino acid metabolism, tRNA synthetases, TCA cycle, electron transport chain and glycolysis.

Targeting early apoptotic genes in batch and fed-batch CHO cell cultures.

Based on the transcriptional profiling of CHO cell culture using microarray, four key early apoptosis signaling genes, Fadd, Faim, Alg-2, and Requiem, were identified and CHO GT (Gene Targeted) cell lines were developed by targeting these four genes. Two were CHO GT(O) cell lines overexpressing anti-apoptotic genes, Faim and Fadd DN and two were CHO GT(KD) cell lines involving knockdown of Alg-2 and Requiem which are pro-apoptotic genes using small interfering RNA (siRNA) technology. Comparisons of these CHO GT cell lines with the parental cell line in batch culture (BC) and fed-batch culture (FBC) were performed. Compared to parental cells, the CHO GT cell lines showed apoptosis resistance as they significantly delayed and/or suppressed initiator caspase-8 and -9 and executioner caspase-3 activities during culture. FBC of CHO GT cell lines reached significantly higher maximum viable cell densities (up to 9 x 10(6) cells/mL) compared with the parental cell line (5 x 10(6) cells/mL). The recombinant interferon gamma (IFN-gamma) yields were increased by up to 2.5-fold. Furthermore, it was observed that the IFN-gamma was more highly sialylated.

Elevation of gamma-glutamyltransferase activity in 293 HEK cells constitutively expressing antisense glutaminase mRNA.

Previous studies have shown that the use of dynamic nutrient feeding to maintain glutamine at low levels in fed-batch cultures reduced the overflow of glutamine metabolism. This strategy resulted in the shift of metabolism towards an energetically more efficient state signified by reduced lactate and ammonia production and thus achieving a higher cell density for enhanced productivity. In an effort to mimic the metabolic changes effected by this fed-batch strategy at the molecular level, 293 HEK cells were engineered via stable transfection with an antisense fragment of the rat phosphate-dependent glutaminase (PDG) gene. PDG is localized in the mitochondria and catalyzes the deamination of glutamine to glutamate with the release of ammonia. Stable single cell clones were isolated from the transfected populations. Characterization of these transfectants revealed indications of an altered glutamine metabolism affected by the antisense strategy. Contrary to our expectations, glutamine consumption and ammonia production in the antisense cells did not deviate significantly from that of untransfected cells. Glutamate was also observed to accumulate to high level extracellularly, as opposed to a consumption pattern normally observed in non-transfected cells. Subsequent analyses show that gamma-glutamyltransferase (gamma-GT) may be a significant pathway that resulted in the formation of glutamate and ammonia from glutamine catabolism extracellularly. gamma-GT has been widely investigated in renal glutamine metabolism, but has rarely been implicated in cultured cell metabolism. This study highlights the importance of this alternative glutamine metabolism pathway in cell culture.

EST sequencing for gene discovery in Chinese hamster ovary cells.

Chinese hamster ovary (CHO) cells are one of the most important cell lines in biological research, and are the most widely used host for industrial production of recombinant therapeutic proteins. Despite their extensive applications, little sequence information is available for molecular based research. To facilitate gene discovery and genetic engineering, two cDNA libraries were constructed from three CHO cell lines grown under various conditions. The average insert size for both libraries is approximately 800-850 bp, and each library has comparable redundancy levels of 36%-38% for the sequences isolated. Random sequencing of 4,608 ESTs yielded 2,602 unique assemblies, 76% of which were annotated as orthologs of sequences in the GenBank database. A high abundance of mitochondrial genome transcripts facilitated the assembly of the complete mitochondrial genome by PCR walking. Comparative analysis of sequences from both mitochondrial and nuclear genomes with orthologous genes from other species shows that CHO sequences are generally most similar to mouse; however, examples with highest similarity to rat or human are common. A cDNA microarray, including all 4,608 ESTs, was constructed. The microarray results reveal a high level of consistency between transcript abundance in the libraries and fluorescence intensities. Inclusion of redundant clones in the microarray, additionally, allows small changes in abundant mRNAs to be discerned with a high degree of confidence. The information and tools generated provide access to genomic technology for this important cell line.