Re-engineering of an Escherichia coli K-12 strain for the efficient production of recombinant human Interferon Gamma.

The Escherichia coli phosphoglucose isomerase (pgi) mutant strain GALG20 was developed previously from wild-type K12 strain MG1655 for increased plasmid yield. To investigate the potential effects of the pgi deletion/higher plasmid levels on recombinant human Interferon Gamma (IFN-γ) production, a detailed network of the central metabolic pathway (100 metabolites, 114 reactions) of GALG20 and MG1655 was constructed. Elementary mode analysis (EMA) was then performed to compare the phenotypic spaces of both the strains and to check the effect of the pgi deletion on flux efficiency of each metabolic reaction. The results suggested that pgi deletion increases amino acid biosynthesis and flux efficiency towards IFN-γ synthesis by 11%. To further confirm the qualitative prediction that the pgi mutation favours recombinant human IFN-γ expression, GALG20 and MG1655 were lysogenised, transformed with a plasmid coding for IFN-γ and tested alongside with BL21(DE3) for their expression capabilities in shake flask experiments using complex media. IFN-γ gene expression was analysed by quantifying plasmid and mRNA copy number per cell and IFN-γ protein production level. Specific IFN-γ yields confirmed the in silico metabolic network predictions, with GALG20(DE3) producing 3.0-fold and 1.5-fold more IFN-γ as compared to MG1655(DE3) and BL21(DE3), respectively. Most of the total IFN-γ was expressed as inclusion bodies across the three strains: 95% in GALG20(DE3), 97% in BL21(DE3) and 72% in MG1655(DE3). The copy number of mRNA coding for IFN-γ was found to be higher in GALG20(DE3) as compared to the other two strains. Overall, these findings show that GALG20(DE3) has the potential to become an excellent protein expression strain.

Fluorescence correlation spectroscopy study of the complexation of DNA hybrids, IgG antibody, and a chimeric protein of IgG-binding ZZ domains fused with a carbohydrate binding module.

Fluorescence correlation spectroscopy (FCS) was used to characterize the molecular interactions between the four components of a DNA recognition system. A fluorescent DNA probe was used to assess: (i) the hybridization with a complementary biotin-labeled target, (ii) the complexation of the resulting hybrid and an anti-biotin antibody, and (iii) the binding of the latter complex to a ZZ-CBM fusion protein that combines small synthetic IgG Fc-binding Z domains with a carbohydrate binding module (CBM). These binding interactions were monitored by exposing the fluorescent DNA probe to different amounts and combinations of the other molecules in solution. Through the analysis of FCS autocorrelation curves, an association constant (Ka) of 2.9 × 107 M-1 was estimated for DNA·DNA hybridization, and the presence of (non-) complementary target DNA in solution could be discriminated. The specific capture of biotinylated DNA hybrids by anti-biotin IgG was verified, with an apparent Ka of 2.5 × 106 M-1. The increment in the diffusion time measured when the DNA·DNA:antibody complexes were in contact with the ZZ-CBM fusion protein suggested that the binding occurs at a stoichiometric ratio of DNA/antibody complex to fusion larger than 1 : 1. The FCS-derived information obtained is useful to gain insight into molecular interactions involved in diagnostic assays.

A biomolecular recognition approach for the functionalization of cellulose with gold nanoparticles.

Materials with new and improved functionalities can be obtained by modifying cellulose with gold nanoparticles (AuNPs) via the in situ reduction of a gold precursor or the deposition or covalent immobilization of pre-synthesized AuNPs. Here, we present an alternative biomolecular recognition approach to functionalize cellulose with biotin-AuNPs that relies on a complex of 2 recognition elements: a ZZ-CBM3 fusion that combines a carbohydrate-binding module (CBM) with the ZZ fragment of the staphylococcal protein A and an anti-biotin antibody. Paper and cellulose microparticles with AuNPs immobilized via the ZZ-CBM3:anti-biotin IgG supramolecular complex displayed an intense red color, whereas essentially no color was detected when AuNPs were deposited over the unmodified materials. Scanning electron microscopy analysis revealed a homogeneous distribution of AuNPs when immobilized via ZZ-CBM3:anti-biotin IgG complexes and aggregation of AuNPs when deposited over paper, suggesting that color differences are due to interparticle plasmon coupling effects. The approach could be used to functionalize paper substrates and cellulose nanocrystals with AuNPs. More important, however, is the fact that the occurrence of a biomolecular recognition event between the CBM-immobilized antibody and its specific, AuNP-conjugated antigen is signaled by red color. This opens up the way for the development of simple and straightforward paper/cellulose-based tests where detection of a target analyte can be made by direct use of color signaling.

Monitoring intracellular calcium in response to GPCR activation using thin-film silicon photodiodes with integrated fluorescence filters.

G-protein coupled receptor (GPCRs) drug discovery is a thriving strategy in the pharmaceutical industry. The standard approach uses living cells to test millions of compounds in a high-throughput format. Typically, changes in the intracellular levels of key elements in the signaling cascade are monitored using fluorescence or luminescence read-out systems, which require external equipment for signal acquisition. In this work, thin-film amorphous silicon photodiodes with an integrated fluorescence filter were developed to capture the intracellular calcium dynamics in response to the activation of the endogenous muscarinic M1 GPCR of HEK 293T cells. Using the new device it was possible to characterize the potency of carbachol (EC50=10.5 µM) and pirenzepine (IC50=4.2 µM), with the same accuracy as standard microscopy optical systems. The smaller foot-print provided by the detection system makes it an ideal candidate for the future integration in microfluidic devices for drug discovery.

Integrated detection of intrinsic fluorophores in live microbial cells using an array of thin film amorphous silicon photodetectors.

Two-dimensional fluorescence spectroscopy (2D FS) provides a non-invasive means to assess cell condition without the introduction of changes to the cell environment. The method relies on the measurement of the excitation-emission fluorescence intensity matrix of key intrinsic fluorophores, like aromatic amino acids, enzyme cofactors, and vitamins. Commonly used detection systems are complex, with multiple bandpass filters, and are hard to miniaturize. Here, an amorphous silicon photodetector array system integrated with amorphous silicon-carbon alloy filters designed to detect three key fluorophores - tryptophan (Trp), reduced nicotine adenine dinucleotide (NADH) and flavin adenine dinucleotide (FAD) - is demonstrated. These intrinsic fluorophores were detected in pure solutions and also in suspended yeast cells. The array system was used to monitor changes in intrinsic fluorophore concentration when a yeast cell solution was subject to a thermal shock stress.

Heterogeneous immunoassays in microfluidic format using fluorescence detection with integrated amorphous silicon photodiodes.

Miniaturization of immunoassays through microfluidic technology has the potential to decrease the time and the quantity of reactants required for analysis, together with the potential of achieving multiplexing and portability. A lab-on-chip system incorporating a thin-film amorphous silicon (a-Si:H) photodiode microfabricated on a glass substrate with a thin-film amorphous silicon-carbon alloy directly deposited above the photodiode and acting as a fluorescence filter is integrated with a polydimethylsiloxane-based microfluidic network for the direct detection of antibody-antigen molecular recognition reactions using fluorescence. The model immunoassay used consists of primary antibody adsorption to the microchannel walls followed by its recognition by a secondary antibody labeled with a fluorescent quantum-dot tag. The conditions for the flow-through analysis in the microfluidic format were defined and the total assay time was 30 min. Specific molecular recognition was quantitatively detected. The measurements made with the a-Si:H photodiode are consistent with that obtained with a fluorescence microscope and both show a linear dependence on the antibody concentration in the nanomolar-micromolar range.

Capture of human monoclonal antibodies from a clarified cell culture supernatant by phenyl boronate chromatography.

In this work, we investigated the feasibility of using phenyl boronate (PB) chromatography for the direct capture of monoclonal antibodies from a CHO cell supernatant. Preliminary results, using pure protein solutions have shown that PB media can bind to human antibodies, not only at strong alkaline conditions but also at acidic pH values. In fact, antibodies have been found to bind in the pH range 5.5-8.5. On the other hand, insulin and human serum albumin did not bind at alkaline pH but at lower pH, which reflects the importance of non-specific interactions with the matrix. Different binding and eluting buffers were evaluated for the capture of immunoglobulin G (IgG) from a CHO cell supernatant and the most promising results were obtained using 20 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid at pH 8.5 as binding buffer and 1.5 M Tris-HCl as eluting buffer. Using a step elution, all IgG was recovered in the elution pool with a maximum purification factor of 56. A gradient elution allowed a further increase of the final purity, yet achieving a slightly lower yield. IgG recovery was around 85% and the purification factor was 76. The highest purity was obtained when the pH of the cell supernatant feed was previously adjusted to 8.5. Starting from an initial protein purity of 1.1% and high-performance liquid chromatography (HPLC) purity of 2.2%, after PB adsorption, a final protein purity of 85% and a HPLC purity of 88% was achieved.

Quantitation of non-amplified genomic DNA by bead-based hybridization and template mediated extension coupled to alkaline phosphatase signal amplification.

Klenow I polymerase activity was combined with solid phase DNA hybridization to detect non-amplified genomic DNA (gDNA) sequences from Escherichia coli. Aminopropyl-controlled pore glass surface-bound oligonucleotides were hybridized to fragmented gDNA. The template-mediated extension at the 3'-terminus of the immobilized probe was then promoted in the presence of Klenow I polymerase and digoxigenin-labeled nucleotides. Detection of the extended probes was accomplished with an anti-digoxigenin alkaline phosphatase conjugate protocol coupled to colorimetric or fluorescent detection. Using the colorimetric protocol, the proof-of-concept was established. The fluorescence-based methodology, on the other hand, provided the basis for a quantitative interpretation of the data, affording a detection limit of 5 pM gDNA.

The effect of the shape of single, sub-ms voltage pulses on the rates of surface immobilization and hybridization of DNA.

Electric fields generated by single square and sinusoidal voltage pulses with amplitudes below 2 V were used to assist the covalent immobilization of single-stranded, thiolated DNA probes, onto a chemically functionalized SiO2 surface and to assist the specific hybridization of single-stranded DNA targets with immobilized complementary probes. The single-stranded immobilized DNA probes were either covalently immobilized (chemisorption) or electrostatically adsorbed (physisorption) to a chemically functionalized surface. Comparing the speed of electric field assisted immobilization and hybridization with the corresponding control reactions (without electric field), an increase of several orders of magnitude is observed, with the reaction timescaled down from 1 to 2 h to a range between 100 ns and 1 ms. The influence of the shape of the voltage pulse (square versus sinusoidal) and its duration were studied for both immobilization and hybridization reactions. The results show that pulsed electric fields are a useful tool to achieve temporal and spatial control of surface immobilization and hybridization reactions of DNA.

Application of central composite design for DNA hybridization onto magnetic microparticles.

Central composite face-centered (CCF) design and response surface methodologies were used to investigate the effect of probe and target concentration and particle number in immobilization and hybridization on a microparticle-based DNA/DNA hybridization assay. The factors under study were combined according to the CCF design matrix, and the intensity of the hybridization signal was quantified by flow cytometry. A second-order polynomial was fitted to data and validated by analysis of variance. The results showed a complex relationship between variables and response given that all factors as well as some interactions were significant, yet it could explain 95% of the data. Probe and target concentration had the strongest impact on hybridization signal intensity. Increments in initial probe concentration in solution positively affected the hybridization signal until a negative influence of a compact probe layer emerged. This trend was attributed to probe-probe interactions. By manipulating particle number on both immobilization and hybridization, enhancements on the assay sensitivity could be obtained. Under optimized conditions, the limit of detection (LOD) at the 95% confidence level was determined to be 2.3 nM of target solution concentration.

The role of probe-probe interactions on the hybridization of double-stranded DNA targets onto DNA-modified magnetic microparticles.

In this work, we have studied the effect of different probe lengths and surface densities on the hybridization of a 181-bp polymerase chain reaction product to probes tethered onto magnetic microparticles. Hybridization was shown to be favored by longer probes but only at probe surface densities where probe-to-probe interactions are absent. From these results, a simple rule was inferred for determining maximum surface densities above which hybridization signals decreased. According to this rule, if the average surface area occupied by an immobilized probe (Sigma) is larger than the projected surface area of each tethered probe molecule (S(ss)), hybridization efficiency increases with surface density, whereas the reverse occurs when Sigma-S(ss) < 0.

Effect of cationic liposomes/DNA charge ratio on gene expression and antibody response of a candidate DNA vaccine against Maedi Visna virus.

Maedi Visna virus (MVV) is an ovine lentivirus with high prevalence all over the world. Since conventional vaccines had failed in protecting animals against the infection, the development of a DNA vaccine can be an alternative. The candidate vaccine was constructed by cloning the sequence encoding MVV p25 protein and was tested both in vitro and in vivo experiments associated with cationic liposomes. The lipoplexes (plasmid DNA-liposome complexes) with charge ratios ranging from 0 to 18 were prepared in physiological saline solution and characterized at a physical-chemistry level. Agarose gel electrophoresis was used as a first approach to evaluate qualitatively the amount of unbounded DNA by the liposomes. Dynamic light scattering measurements revealed that under the studied conditions lipoplexes with theoretical charge ratios (+/-) from 3 to 6 are unstable and prone to aggregation displaying sizes higher than 1 microm. At lower and higher charge ratios lipoplex size range from 200 to 500 nm. Using a Foster Resonance Energy Transfer methodology previously reported by us, complexation efficiency of the same complexes was related to in vitro and in vivo results. Higher transfection efficiencies were obtained in vitro with lipoplexes with charge ratio (+/-)=10, where 97% of the DNA were protected by the liposomes. However, the subcutaneous immunization of mice induced higher antibody titers with lipoplexes at charge ratio (+/-)=1, in which only 23% DNA is protected by the liposomes. Moreover, use of cationic liposomes has shown an increased antibody response when compared with a naked DNA immunization.

Histidine affinity chromatography of homo-oligonucleotides. Role of multiple interactions on retention.

The recent application of histidine-agarose affinity supports in plasmid purification takes advantage of the biorecognition of nucleic acid bases by the histidine ligand. This consideration prompted the need for better understanding the interactions involved in affinity chromatography of plasmid DNA with the histidine-agarose support. In this work, we used synthetic homo-deoxyoligonucleotides with different sizes (1-30 nucleotides long), to explore the effect of several conditions like hydrophobic character of the individual bases, presence of secondary structures, temperature, pH and salt concentration on the mechanism of retention of nucleic acids to histidine-agarose support. One of the most striking results shows that histidine interacts preferentially with guanine, and the presence of secondary structures on polyA and polyG oligonucleotides has a significant influence on retention. Otherwise, the temperature manipulation has not shown a direct influence on oligonucleotide retention, only inducing conformational changes on secondary structures. Overall, the results obtained provide valuable information for the future development and implementation of histidine and other amino acids as ligands in chromatography for the purification of plasmid DNA and other nucleic acids, by improving the knowledge of the interactions involved as well as of the parameters influencing the retention.

Evaluation of the effect of non-B DNA structures on plasmid integrity via accelerated stability studies.

Plasmid biopharmaceuticals are a new class of medicines with an enormous potential. Attempts to increase the physical stability of highly purified supercoiled (SC) plasmid DNA in pharmaceutical aqueous solutions have relied on: (i) changing the DNA sequence, (ii) improving manufacturing to reduce deleterious impurities and initial DNA damage, and (iii) controlling the storage medium characteristics. In this work we analyzed the role of secondary structures on the degradation of plasmid molecules. Accelerated stability experiments were performed with SC, open circular (OC) and linear (L) isoforms of three plasmids which differed only in the "single-strandlike" content of their polyadenylation (poly A) signals. We have proved that the presence of more altered or interrupted (non-B) DNA secondary structures did not directly translate into an easier strand scission of the SC isoforms. Rather, those unusual structures imposed a lower degree of SC in the plasmids, leading to an increase in their resistance to thermal degradation. However, this behavior was reversed when the relaxed or L isoforms were tested, in which case the absence of SC rendered the plasmids essentially double-stranded. Overall, this work suggests that plasmid DNA sequence and secondary structures should be taken into account in future investigations of plasmid stability during prolonged storage.

Binding and elution strategy for improved performance of arginine affinity chromatography in supercoiled plasmid DNA purification.

New interesting strategies for plasmid DNA (pDNA) purification were designed, exploiting affinity interactions between amino acids and nucleic acids. The potential application of arginine-based chromatography to purify pDNA has been recently described in our work; however, to achieve higher efficiency and selectivity in arginine affinity chromatography, it is essential to characterize the behaviour of binding/elution of supercoiled (sc) isoforms. In this study, two different strategies based on increased sodium chloride (225-250 mm) or arginine (20-70 mm) stepwise gradients are described to purify sc isoforms. Thus, it was proved that well-defined binding/elution conditions are crucial to enhance the purification performance, resulting in an improvement of the final plasmids yields and transfection efficiency, as this could represent a significant impact on therapeutic applications of the purified sc isoform.

Detection of DNA and proteins using amorphous silicon ion-sensitive thin-film field effect transistors.

Amorphous silicon-based ion-sensitive field-effect transistors (a-Si:H ISFETs) are used for the label-free detection of biological molecules. The covalent immobilization of DNA, followed by DNA hybridization, and of the surface adsorption of oligonucleotides and proteins were detected electronically by the a-Si:H ISFET. The ISFET measurements are performed with an external Ag/AgCl microreference electrode immersed in 100mM phosphate buffer electrolyte with pH 7.0. Threshold voltage shifts in the transfer curve of the ISFETs are observed resulting from successive steps of surface chemical functionalization, covalent DNA attachment to the functionalized surface, surface blocking, and hybridization with a complementary target. The surface sensitivity achieved for DNA oligonucleotides is of the order of 1pmol/cm(2). Point-of-zero charge estimations were made for the functionalized surfaces and for the device surface after DNA immobilization and hybridization. The results show a correlation between the changes in the point-of-zero charge and the shift observed in the threshold voltage of the devices. Electronic detection of adsorbed proteins and DNA is also achieved by monitoring the shifts of the threshold voltage of the ISFETs, with a sensitivity of approximately 50nM.

Chemiluminescent bead-based hybridization assay for the detection of genomic DNA from E. coli in purified plasmid samples.

A bead-based hybridization assay was developed for detection of traces of E. coli genomic DNA (gDNA) present in purified plasmid DNA (pDNA) samples. Standards of gDNA and pDNA samples were sheared by sonication and adsorbed onto aminopropyl controlled pore glass (CPG) particles (130 microm). A preliminary study was conducted to optimize the amount of DNA adsorbed on the particles. Results indicated that maximum attachment efficiency was obtained by adsorbing DNA for 2 h in 0.2 x SSC, pH 5.7. The DNA-bound particles were hybridized overnight with a 181-bp digoxigenin-labeled probe, specific for gDNA. Following a chemiluminescent detection protocol, signal intensities of the standards were plotted as a function of initial gDNA concentration. The calculated detection limit (LOD) was 1.4 pM of gDNA. The assay was able to detect gDNA in pure plasmid preparations at the 1% level even in the presence of 1,000-fold excess of noncomplementary target. Hybridization results were compared with a quantitative real-time PCR assay. Both methods afforded similar accurate results at the 95% confidence level.

Specific recognition of supercoiled plasmid DNA in arginine affinity chromatography.

Arginine chromatography was used to fully separate supercoiled and open circular plasmid DNA (pDNA) isoforms. The results show that the arginine matrix promotes multiple interactions with pDNA, including not only electrostatic and hydrophobic but also biorecognition of nucleotide bases by the arginine ligand. The strong interactions occurring with DNA backbone provide stability, conducting to high effectiveness of arginine support to bind pDNA at low ionic strength. The specific interaction of arginine with sc pDNA could be due to the ability of arginine matrix to be involved in complex interactions that are partly dependent on the conformation of the DNA molecule.

Prediction of diffusion coefficients of plasmids.

The ability to predict diffusion coefficients is important in the design, analysis, and operation of plasmid downstream processing operations such as membrane and fixed-bed chromatography. A correlation is proposed to predict the diffusion coefficient, D, of supercoiled plasmid DNA molecules in dilute solutions on the basis of the molecular weight, M, or size. Experimental data (18 points) collected from the literature confirmed the proposed variation of D with plasmid molecular weight as D proportional, variant M(-2/3), for molecules within the 1,800-287,100 base-pair range. The correlation was able to estimate the available experimental results with an average error of 6.3%.

On the stability of plasmid DNA vectors during cell culture and purification.

Gene therapy and DNA vaccination applications have increased the demand for highly purified plasmid DNA (pDNA) in the last years. One of the main problems related to the scale-up of pDNA purification is the degradation of the supercoiled (sc) isoforms during cell culture and multi-stage purification. In this work, a systematic study of the stability of two model plasmids (3,697 and 6,050 bp) during a mid-scale production process, which includes fermentation, alkaline lysis, isopropanol and ammonium sulphate precipitation and hydrophobic interaction chromatography, was performed. Results indicate that by extending cell culture (up to 26 h) and cell lysis (up to 2 h) it is possible to significantly reduce the amounts of RNA, without significantly compromising the yields of the sc pDNA isoform, a feature that could be conveniently exploited for downstream processing purposes. The stability of pDNA upon storage of E. coli pellets at different temperatures indicates that, differently from RNA, pDNA is remarkably stable when stored in cell pellets (>3 weeks at 4 degrees C, >12 weeks at -20 degrees C) prior to processing. With alkaline lysates, however, storage at -20 degrees C is mandatory to avoid sc pDNA degradation within the first 8 weeks. Furthermore, the subsequent purification steps could be carried out at room temperature without significant pDNA degradation. Since the unit operations and process conditions studied in this work are similar to those generally used for plasmid DNA production, the results presented here may contribute to improve the current knowledge on plasmid stability and process optimization.