Production and Use of Gesicles for Nucleic Acid Delivery.

Over-expression of the vesicular stomatitis virus glycoprotein (VSVG) in mammalian cells can induce the formation of VSVG-pseudotyped vesicles (named "gesicles") from membrane budding. Its use as a nucleic acid delivery tool is still poorly documented. Naked-plasmid DNA can be delivered in animal cells with gesicles in presence of hexadimethrine bromide (polybrene). However, little is known about gesicle manufacturing process and conditions to obtain successful nucleic acid delivery. In this study, gesicles production process using polyethylenimine (PEI)-transfected HEK293 cells was developed by defining the VSVG-plasmid concentration, the DNA:PEI mass ratio, and the time of gesicle harvest. Furthermore, parameters described in the literature relevant for nucleic acid delivery such as (i) component concentrations in assembly mixture, (ii) component addition order, (iii) incubation time, and (iv) polybrene concentration were tested by assessing the transfection capacity of the gesicles complexed with a green fluorescent protein (GFP)-coding plasmid. Interestingly, freezing/thawing cycles and storage at + 4 °C, - 20 °C, and - 80 °C did not reduce gesicles' ability to transfer plasmid DNA. Transfection efficiency of 55% and 22% was obtained for HeLa cells and for hard-to-transfect cells such as human myoblasts, respectively. For the first time, gesicles were used for delivery of a large plasmid (18-kb) with 42% of efficiency and for enhanced green fluorescent protein (eGFP) gene silencing with siRNA (up to 60%). In conclusion, gesicles represent attractive bioreagents with great potential to deliver nucleic acids in mammalian cells.

Transduction Efficiency of Adenovirus Vectors in Endothelial Cells and Vascular Smooth Muscle Cells.

Adenoviral vectors are useful tools in manipulating a gene of interest in vitro and in vivo, including in the vascular system. The transduction efficiencies of adenoviral vectors in vascular cells such as endothelial cells (ECs) and vascular smooth muscle cells (VSMCs) are known to be lower than those in epithelial cell types. The effective entry for adenoviral vectors is primarily mediated through the coxsackievirus and adenovirus receptor (CAR), which has been shown to be expressed in both cell types. Cationic liposomes have been used to enhance adenovirus transduction efficiency in nonepithelial cells. Accordingly, the aim of this study is to obtain new information regarding differences in transduction efficiencies, cationic liposome sensitivity, and CAR expression between ECs and VSMCs. Using cultured rat aortic ECs and VSMCs, here, we have compared transduction efficiency of adenoviruses with or without inclusion of liposomes and CAR expression. A significant increase in basal transduction efficiency was observed in ECs compared with VSMCs. Cationic liposome polybrene enhanced transduction efficiency in VSMCs, whereas decreased efficiency was observed in ECs. Western blotting demonstrated expression of the CAR in ECs but not in VSMCs. Proteomic analysis and mouse aorta immunostaining further suggests significant expression of the CAR in ECs but not in VSMCs. In conclusion, adenoviruses can effectively transduce the gene of interest in aortic ECs likely because of abundant expression of the CAR, whereas cationic liposomes such as polybrene enhance the transduction efficiency in VSMCs lacking CAR expression.

Screening of inhibitors against histone demethylation jumonji domain-containing protein 3 by capillary electrophoresis.

Jumonji domain-containing proteins (JMJDs) play an important role in the epigenetic regulation of gene expression. Aberrant regulation of histone modification has been observed in the progression of a variety of diseases, such as neurological disorders and cancer. Therefore, discovery of selective modulators of JMJDs is very attractive in new drug discovery. Herein, a simple capillary electrophoresis (CE) method was developed for screening of inhibitors against JMJD3. A known JMJD3 inhibitor GSK-J1, 5-carboxyfluorescein labeled substrate peptide with an amino acid sequence of KAPRKQLATKAARK(me3)SAPATGG (truncated from histone H3), as well as a small chemical library composed of 37 purified natural compounds and 30 natural extracts were used for method development and validation. The separation of substrate from its demethylated product was achieved by addition of polycation hexadimethrine bromide (HDB) in the running buffer. The enzyme activity was thus assayed accurately through separating the demethylated product from the substrate and then measuring the peak area of the product. The enzyme inhibition can be read out by comparing the peak area of the demethylated product obtained in the present of inhibitors and that of the negative control in the absence of any inhibitor. The merit of the method is proved by discovering two new JMJD3 inhibitors: salvianic acid A and puerarin 6''-O-xyloside.

Electrokinetic motion of a micro oil droplet under a glass slide.

Electrokinetic motion of a micro oil droplet beneath a glass slide was experimentally investigated in this paper. The micro oil droplets were released under the glass slide in an aqueous solution and the motion along the glass slide was measured by a microscope. The experimental results indicate that while the electrokinetic mobility increases with the applied electric field, it decreases with the oil droplet size and the ionic concentration of the aqueous solution, respectively. By changing the zeta potential of the glass-liquid interface using polybrene coating from negative to positive, the direction of the electrokinetic mobility is reversed and the absolute value of the electrokinetic mobility increases significantly. Finally, pH effects were also investigated, and it was found that the electrokinetic mobility of the droplets reaches a maximum at pH = 6∼8.

Capillary electrophoresis-based assessment of nanobody affinity and purity.

Drug purity and affinity are essential attributes during development and production of therapeutic proteins. In this work, capillary electrophoresis (CE) was used to determine both the affinity and composition of the biotechnologically produced "nanobody" EGa1, the binding fragment of a heavy-chain-only antibody. EGa1 is an antagonist of the epidermal growth factor receptor (EGFR), which is overexpressed on the surface of tumor cells. Using a background electrolyte (BGE) of 50mM sodium phosphate (pH 8.0) in combination with a polybrene-poly(vinylsulfonic acid) capillary coating, CE analysis of EGa1 showed the presence of at least three components. Affinity of the EGa1 components towards the extracellular domain of EGFR was assessed by adding different concentrations (0-12 nM) of the receptor to the BGE while measuring the effective electrophoretic mobility of the respective EGa1 components. Binding curves obtained by plotting electrophoretic mobility shifts as a function of receptor concentration, yielded dissociation constants (Kd) of 1.65, 1.67, and 1.75 nM for the three components, respectively; these values were comparable to the Kd of 2.1 nM obtained for the bulk EGa1 product using a cellular assay. CE with mass spectrometry (MS) detection using a BGE of 25 mM ammonium acetate (pH 8.0) revealed that the EGa1 sample comprised of significant amounts of deamidated, bisdeamidated and N-terminal pyroglutamic acid products. CE-MS using a BGE of 100mM acetic acid (pH 2.8) in combination with a polybrene-dextran sulfate-polybrene capillary coating demonstrated the additional presence of minor products related to incomplete removal of the signal peptide from the produced nanobody. Combining the results obtained from affinity CE and CE-MS, it is concluded that the EGa1 nanobody product is heterogeneous, comprising highly-related proteins that exhibit very similar affinity towards EGFR.

Analysis of urinary metabolites for breast cancer patients receiving chemotherapy by CE-MS coupled with on-line concentration.

OBJECTIVE: This study aimed to explore the relationship between urinary metabolites and clinical chemotherapy response in breast cancer by CE-MS coupled with on-line concentration. DESIGN AND METHODS: Urine samples were obtained from patients with advanced or locally advanced breast cancer (n=21) before and after chemotherapy and healthy volunteers (n=21). A rapid and sensitive hexadimethrine bromide-coating CE-MS method coupled with normal stacking is developed for the determination of organic acids in human urine. Another CE-MS method coupled with pH-mediated sample stacking is used for the analysis of amino acids and organic acids. RESULTS: After receiving chemotherapy, chemotherapy-sensitive patients showed 30% change in metabolite levels compared to healthy people, while chemotherapy-insensitive patients showed only 9% change in metabolite levels compared to healthy people showing recurrence. The extent of energy insufficiency for chemotherapy-insensitive patients was greater than that for chemotherapy-sensitive patients. CONCLUSIONS: Urinary metabolic products may be new potential predictive markers for therapy efficacy. However, more studies with a larger sample size are required to confirm these conclusions.

Advantages and limitations of a new cationic coating inducing a slow electroosmotic flow for CE-MS peptide analysis: a comparative study with commercial coatings.

Capillary coatings are crucial for high-quality separation performance in capillary electrophoresis analysis of proteins or peptides as they prevent analyte adsorption at the capillary wall. These coating materials have to fulfill many requirements such as a good separation performance and ensuring a good repeatability. The number of commercially available coating materials is still limited, especially with regard to the charge density on the coating material and the induced electroosmotic flow (EOF) velocity. In this work, we compare the separation performance of the novel self-made cationic capillary coating OHNOON and two commercially available coating materials, the acrylamide based, neutral LN® and the cationic hexadimethrine bromide (Polybrene), using the same coating procedure for all three coating materials. The coatings are investigated regarding the separation efficiency, analyte resolution, coating stability, and migration time stability in tryptic peptide analysis. Good separation performance was confirmed for all three coating materials: all coatings provided high plate numbers of up to 400,000-500,000 and a repeatability of the EOF and the analyte migration times in the range of 1% relative standard deviation or below. Our results reveal a moderate EOF velocity for the novel OHNOON coating in comparison to the Polybrene coating. We present a detailed discussion of the impact of this reduced EOF velocity and the separation performance. The results presented here will help to define the necessary properties of coating materials to achieve the best compromise between speed of analysis and resolution for the respective application. We show that our novel OHNOON coating is especially valuable for the analysis of low mobility analytes and for samples with a broad range of analyte mobilities.

A highly sensitive capillary electrophoresis method using p-nitrophenyl 5'-thymidine monophosphate as a substrate for the monitoring of nucleotide pyrophosphatase/phosphodiesterase activities.

A highly sensitive capillary electrophoresis method has been developed to monitor the activity of nucleotide pyrophosphatases/phosphodiesterases (NPPs) and screen for NPP inhibitors. In this method, p-nitrophenyl 5'-thymidine monophosphate (p-Nph-5'-TMP) was used as an artificial substrate, and separation of reaction products was performed on a dynamically coated capillary. We found that the optimal capillary electrophoresis (CE) conditions were as follows: fused-silica capillary (20cm effective length×75.5µm (id)), electrokinetic injection for 60s, 70mM phosphate buffer containing polybrene 0.002%, pH 9.2, constant current of -80µA, constant capillary temperature of 15°C and detection at 400nm. To allow precise quantification, 2-methyl-4,6-dinitrophenol (dinitrocresol) was applied as an internal standard. The limit of detection (LOD) and the limit of quantification (LOQ) were 137 and 415nM, respectively. This new method was shown to be over 8-fold more sensitive than the conventional spectrophotometric assays and 16-fold more than the previously reported CE procedure, and the results (K(m) values for NPP1 and NPP3, K(i) values for standard inhibitors) obtained were in accordance with previous literature data. Therefore, this new method is an improvement of actual techniques and could be used as a quick and standard analytical technique for the identification and characterization of NPP inhibitors.

Transduction of human cells with polymer-complexed ecotropic lentivirus for enhanced biosafety.

Stem and tumor cell biology studies often require viral transduction of human cells with known or suspected oncogenes, raising major safety issues for laboratory personnel. Pantropic lentiviruses, such as the commonly used VSV-G pseudotype, are a valuable tool for studying gene function because they can transduce many cell types, including non-dividing cells. However, researchers may wish to avoid production and centrifugation of pantropic viruses encoding oncogenes due to higher biosafety level handling requirements and safety issues. Several potent oncogenes, including c-Myc and SV40 large T antigen, are known to enhance production of induced pluripotent stem cells (iPSC). All other known iPSC-inducing genetic changes (OCT4, SOX2, KLF4, NANOG, LIN28, and p53 loss of function) also have links to cancer, making them of relatively high safety concern as well. While these cancer-related viruses are useful in studying cellular reprogramming and pluripotency, they must be used safely. To address these biosafety issues, we demonstrate a method for transduction of human cells with ecotropic lentivirus, with additional emphasis on reduced cost and convenient handling. We have produced ecotropic lentivirus with sufficiently high titer to transduce greater than 90% of receptor-expressing human cells exposed to the virus, validating the efficacy of this approach. Lentivirus is often concentrated by ultracentrifugation; however, this process takes several hours and can produce aerosols infectious to human biomedical researchers. As an alternative, viral particles can be more safely sedimented onto cells by complexation with chondroitin sulfate and polybrene (CS/PB). This technique increases the functional viral titer up to 3-fold in cells stably expressing murine retrovirus receptor, with negligible added time and cost. Transduction of human dermal fibroblasts (HDFs) is maximally enhanced using CS/PB concentrations approximately 4-fold lower than the optimal value previously reported for cancer cell lines, suggesting that polymer concentration should be titrated for the target cell type of interest. We therefore describe the use of methylthiazolyldiphenyl-tetrazolium bromide (MTT) to assay for polymer toxicity in a new cell type. We observe equivalent viability of HDFs after viral transduction using either polymer complexation or the standard dose of polybrene (PB, 6 µg/ml), indicating minimal acute toxicity. In this protocol, we describe the use of ecotropic lentivirus for overexpression of oncogenes in human cells, reducing biosafety risks and increasing the transduction rate. We also demonstrate the use of polymer complexation to enhance transduction while avoiding aerosol-forming centrifugation of viral particles.

Investigation of prothrombin time in human whole-blood samples with a quartz crystal biosensor.

Monitoring of blood coagulation and fibrinolysis is an important issue in treatment of patients with cardiovascular problems and in surgery when blood gets into contact with artificial surfaces. In this work a new method for measuring the coagulation time (prothrombin time, PT) of human whole-blood samples based on a quartz crystal microbalance (QCM) biosensor is presented. The 10 MHz sensors used in this work respond with a frequency shift to changes in viscosity during blood clot formation. For driving and for readout of the quartz, both a network analyzer and an oscillator circuit were utilized. The sensor surfaces were specifically coated with a thin polyethylene layer. We found that both frequency analysis methods are suitable to measure exact prothrombin times in a very good conformity with a mechanical coagulometer as a reference. The anticoagulant effect of heparin on the prothrombin time was exemplarily shown as well as the reverse effect of the heparin antagonist polybrene. The change of the viscoelastic properties during blood coagulation, reflected by the ratio of frequency and dissipation shifts, is discussed for different dilutions of the whole-blood samples. In conclusion, QCM is a distinguished biosensor technique to determine prothrombin time and to monitor heparin therapy in whole-blood samples. Due to the excellent potential of miniaturization and the availability of direct digital signals, the method is predestinated for incorporation and integration into other devices and is thus opening the field of application for inline coagulation diagnostic in extracorporeal blood circuits.

Evaluation of migration behaviour of therapeutic peptide hormones in capillary electrophoresis using polybrene-coated capillaries.

Modelling electrophoretic mobility as a function of pH can be simultaneously used for determination of ionization constants and for rapid selection of the optimum pH for separation of mixtures of the modelled compounds. In this work, equations describing the effect of pH on electrophoretic behaviour were used to investigate migration of a series of polyprotic amphoteric peptide hormones between pH 2 and 12 in polybrene-coated capillaries. Polybrene (hexadimethrin bromide) is a polymer composed of quaternary amines that is strongly adsorbed by the fused-silica inner surface, preventing undesired interactions between the peptides and the inner capillary wall. In polybrene-coated capillaries the separation voltage must be reversed, because of the anodic electroosmotic flow promoted by the polycationic polymer attached to the inner capillary wall. The possibility of using polybrene-coated capillaries for determination of accurate ionization constants has been evaluated and the optimum pH for separation of a mixture of the peptide hormones studied has been selected. Advantages and disadvantages of using bare fused-silica and polybrene-coated capillaries for these purposes are discussed.

Parviz Lalezari: an autobiography.

Doctor Parviz Lalezari, currently a clinical professor of Medicine and Pathology at Albert Einstein College of Medicine in New York, describes highlights of his research career since 1958. He became the director of the blood bank at Montefiore Hospital in New York City in 1961, director of the Division of Immunohematology until 1996, and then until 2001, was President and chief executive officer of the Bergen Community Regional Blood Center in New Jersey. Doctor Lalezari was born in Iran in 1931, and after graduation from Medical School, he came to the United States in 1956. His initial research was on leukocyte antibodies. After modifying the available antibody detection techniques, he discovered that like hemolytic disease of the newborn and neonatal immune thrombocytopenia, fetal-maternal neutrophil incompatibility can cause neonatal neutropenia. He identified the targets of these antibodies and showed that they were expressed only on peripheral blood neutrophils. Doctor Lalezari also discovered that a common form of neutropenia in early childhood was caused by development of autoantibodies, which surprisingly were directed against the same neutrophil-specific antigens involved in fetal-maternal incompatibility. In 1959, a heparin-neutralizing drug (Polybrene) was introduced to be used after open-heart surgery. Lalezari discovered that Polybrene, a quaternary ammonium polymer, reacted with sialic acid molecules on the red blood cell (RBC) surface, causing the RBCs to aggregate. Later, realizing that the repelling forces generated by the RBC surface membrane charges were responsible for failure of the small IgG antibody molecules to agglutinate the RBCs, he used Polybrene to neutralize the RBC surface negative charge to allow the IgG antibody molecules to induce hemagglutination. This became The Polybrene test, which is to be used in RBC antibody detection.

Efficient and highly reproducible capillary electrophoresis-mass spectrometry of peptides using Polybrene-poly(vinyl sulfonate)-coated capillaries.

The potential of capillaries noncovalently coated with a bilayer of oppositely charged polymers for the analysis of peptides by CE-MS was investigated. Bilayer coatings were produced by subsequently rinsing fused-silica capillaries with a solution of Polybrene (PB) and poly(vinyl sulfonate) (PVS). The PB-PVS coating showed to be fully compatible with MS detection causing no ionization suppression or background signals. The bilayer coating provided a considerable EOF at low pH, thereby facilitating the fast separation of peptides using a BGE of formic acid (pH 2.5). Under optimized CE-MS conditions, for enkephalin peptides high separation efficiencies were obtained with plate numbers in the range of 300,000-500,000. It is demonstrated that both the cancellation of the hydrodynamic capillary flow induced by the nebulizer gas and a sufficiently high-data acquisition rate are crucial for achieving these efficiencies. The overall performance of the CE-MS system using PB-PVS-coated capillaries was evaluated by the analysis of a tryptic digest of cytochrome c. The system provided an efficient separation of the peptide mixture, which could be effectively monitored by MS/MS detection allowing identification of at least 13 peptides within a time interval of 1.5 min. In addition, the PB-PVS coating proved to be very consistent yielding stable CE-MS patterns with highly favorable migration time reproducibilities (RSDs < 1% over a 3-day period).

Complexation with chondroitin sulfate C and Polybrene rapidly purifies retrovirus from inhibitors of transduction and substantially enhances gene transfer.

Using amphotropic retrovirus stocks produced by TELCeB6-A cells that encode the Escherichia coli lacZ gene, we found that complexation with chondroitin sulfate C (CSC) and Polybrene (PB) is an effective means to purify retrovirus. Virus stocks contained high levels of inhibitory activity that blocked amphotropic, but not ecotropic, retrovirus transduction. When virus stocks were brought to 80 microg/mL each of CSC and PB, complexes of CSC and PB formed. These complexes incorporated more than 70% of the virus particles but less than 0.4% of all other proteins and no detectable inhibitory activity. Purified virus transduced NIH 3T3 murine fibroblasts 21 to 186-fold more efficiently than virus that was not purified. In addition, virus purification significantly altered the dose response of transduction. When virus that had not been purified was used to transduce cells, the relationship between transduction and virus concentration was highly non-linear. In contrast, when purified virus was used, transduction increased monotonically and was linearly proportional to virus concentration, except when high doses of virus were used. Interestingly, when high doses of virus were used gene transfer reached a maximum plateau level, most likely because particle-associated amphotropic envelope proteins had saturated the cellular receptors for the virus. Our findings illustrate that retrovirus purification increases the maximum number of genes that can be transferred, reduces the amount of virus required to achieve a given level of gene transfer, and reduces uncertainties about the relationship between the amount of virus used and the number of genes transferred.

Highly efficient transduction of repopulating bone marrow cells using rapidly concentrated polymer-complexed retrovirus.

Using the cationic polymer, Polybrene, and the anionic polymer, chondroitin sulfate C, we concentrated recombinant retrovirus pseudotyped with an ecotropic envelope, which is susceptible to inactivation by high-speed concentration methods. To evaluate gene marking, murine bone marrow was harvested from C3H mice, transduced with polymer-concentrated GFP virus, and transplanted into lethally irradiated recipients. Total gene marking in mice averaged 30-35% at 8 weeks post-transplant and transgene expression remained stable for over 16 weeks. Using the polymer concentration method, a second retroviral vector encoding the drug resistant variant of dihydrofolate reductase (L22Y-DHFR) was concentrated and tested. Approximately 40% of transduced murine bone marrow progenitor cells were protected against trimetrexate concentrations that completely eliminated the growth of non-modified cells. These results show that anionic and cationic polymers can be combined to rapidly concentrate viruses that are normally difficult to concentrate, and the concentrated virus efficiently transduces hematopoietic stem cells.

Efficient and reproducible analysis of peptides by capillary electrophoresis using noncovalently bilayer-coated capillaries.

The usefulness of a noncovalent capillary coating consisting of two layers of oppositely charged polymers for the separation of peptides with capillary electrophoresis (CE) was studied. Capillaries were coated simply by subsequently flushing with solutions of 1% m/v Polybrene and 1% v/v poly(vinylsulfonate) (PVS) forming a bilayer, which showed to produce a strong and highly reproducible electroosmotic flow (EOF) at low pH. Using this coating in combination with a background electrolyte (BGE) containing sodium phosphate (pH 2.5) and 0.01% v/v PVS, initially broadened and overlapping peaks were obtained for some test peptides. By omitting the PVS from the BGE, the peak width and shape of the peptides improved resulting in baseline separation. A systematic study of the influence of the BGE composition showed that considerable further enhancement of the separation efficiency was achieved by increasing the ionic strength of the BGE. Using a BGE of 200 mM tris(hydroxymethyl)aminomethane (Tris)-phosphate (pH 2.5) plate numbers for the peptides were in the 300 000-600 000 range and the relative standard deviation of the peptide migration times was less then 0.3% (n = 5). The use of Tris-phosphate instead of sodium phosphate allowed the current to stay within acceptable limits when 30 kV was used as separation voltage. Overall, the bilayer coating showed a remarkable EOF repeatability, as well as long-term stability. Compared to bare fused-silica capillaries the intraday and interday repeatability of migration times was very favorable and coated capillaries could be used for over a month performing analyses with low and high ionic strength BGEs without any performance deterioration. The usefulness of the bilayer-coated capillaries for the analysis of positively charged peptides was demonstrated by the fast and efficient separation of various closely related enkephalins and the baseline separation of an isomeric peptide/peptoid couple exhibiting efficiencies of over 550 000 plates.

Charged polymers modulate retrovirus transduction via membrane charge neutralization and virus aggregation.

The specific mechanisms of charged polymer modulation of retrovirus transduction were analyzed by characterizing their effects on virus transport and adsorption. From a standard colloidal perspective two mechanisms, charge shielding and virus aggregation, can potentially account for the experimentally observed changes in adsorption behavior and biophysical parameters due to charged polymers. Experimental testing revealed that both mechanisms could be at work depending on the characteristics of the cationic polymer. All cationic polymers enhanced adsorption and transduction via charge shielding; however, only polymers greater than 15 kDa in size were capable of enhancing these processes via the virus aggregation mechanism, explaining the higher efficiency enhancement of the high molecular weight molecules. The role of anionic polymers was also characterized and they were found to inhibit transduction via sequestration of cationic polymers, thereby preventing charge shielding and virus aggregation. Taken together, these findings suggest the basis for a revised physical model of virus transport that incorporates electrostatic interactions through both virus-cell repulsive and attractive interactions, as well as the aggregation state of the virus.

Complexation of retrovirus with cationic and anionic polymers increases the efficiency of gene transfer.

Previously, we have demonstrated that chondroitin sulfate proteoglycans and glycosaminoglycans inhibit retrovirus transduction. While studying the mechanism of inhibition, we found that the combined addition of equal-weight concentrations (80 microg/ml) of Polybrene and chondroitin sulfate C to retrovirus stocks resulted in the formation of a high-molecular-weight retrovirus-polymer complex that could be pelleted by low-speed centrifugation. The pelleted complex contained more than 80% of the virus particles, but less than 0.3% of the proteins that were originally present in the virus stock. Surprisingly, the virus in the complex remained active and could be used to transduce cells. The titer of the pelleted virus, when resuspended in cell culture medium to the starting volume, was three-fold greater than the original virus stock. The selectivity (CFU/mg protein) of the process with respect to virus activity was more than 1000-fold. When the pelleted virus-polymer complex was resuspended in one-eighth of the original volume and used to transduce NIH 3T3 murine fibroblasts and primary human fibroblasts, gene transfer was increased 10- to 20-fold over the original unconcentrated retrovirus stock. The implications of our findings for the production, processing, and use of retrovirus stocks for human gene therapy protocols are discussed.