Continuous flow electrophoretic separation of proteins and cells from mammalian tissues

Methods of Generating Dielectrophoretic Force for Microfluidic Manipulation of Bioparticles

Manipulation of microscale bioparticles including living cells is of great significance to the broad bioengineering and biotechnology fields. Dielectrophoresis (DEP), which is defined as the interactions between dielectric particles and the electric field, is one of the most widely used techniques for the manipulation of bioparticles including cell separation, sorting, and trapping. Bioparticles experience a DEP force if they have a different polarization from the surrounding media in an electric field that is nonuniform in terms of the intensity and/or phase of the electric field. A comprehensive literature survey shows that the DEP-based microfluidic devices for manipulating bioparticles can be categorized according to the methods of creating the nonuniformity via patterned microchannels, electrodes, and media to generate the DEP force. These methods together with the theory of DEP force generation are described in this review, to provide a summary of the methods and materials that have been used to manipulate various bioparticles for various specific biological outcomes. Further developments of DEP-based technologies include identifying materials that better integrate with electrodes than current popular materials (silicone/glass) and improving the performance of DEP manipulation of bioparticles by combining it with other methods of handling bioparticles. Collectively, DEP-based microfluidic manipulation of bioparticles holds great potential for various biomedical applications.

A Sex-Dependent, Tropic Role for Leptin in the Somatotrope as a Regulator of POU1F1 and POU1F1-Dependent Hormones

Pituitary somatotropes perform the key function of coordinating organismic growth and body composition with metabolic signals. However, the mechanism by which they sense and respond to metabolic signals via the adipokine leptin is unknown. The complex interplay between the heterogeneous cell types of the pituitary confounds the identification of somatotrope-specific mechanisms. Somatotropes represent 30%-40% of the anterior pituitary population and are derived from a lineage of cells that are activated by the Pit-Oct-Unc domain family domain class 1 transcription factor 1 (POU1F1) to produce GH, prolactin (PRL). and TSH. To determine the mechanism by which leptin controls somatotrope function, we used Cre-LoxP technology and fluorescence-activated cell sorting to purify and study control or leptin receptor-deleted (Lepr null) somatotropes. We report that Lepr-null somatotropes show significant reductions in GH protein (GH) and Gh mRNA. By contrast, enzyme immunoassays detected no changes in ACTH, LH, and FSH levels in mutants, indicating that the control of these hormones is independent of leptin signaling to somatotropes. Reduced TSH and PRL levels were also observed, but interestingly, this reduction occurred only in in Lepr-null somatotropes from mutant females and not from males. Consistent with the sex-specific reduction in Gh mRNA, TSH, and PRL, enzyme immunoassays detected a sex-specific reduction in POU1F1 protein levels in adult female Lepr-null somatotropes. Collectively, this study of purified Lepr-null somatotropes has uncovered an unexpected tropic role for leptin in the control of POU1F1 and all POU1F1-dependent hormones. This supports a broader role for somatotropes as metabolic sensors including sex-specific responses to leptin.

Measuring electrical and mechanical properties of red blood cells with double optical tweezers

Red blood cell (RBC) aggregation in the blood stream is prevented by the zeta potential created by its negatively charged membrane. There are techniques, however, to decrease the zeta potential and allow cell agglutination, which are the basis of most of antigen-antibody tests used in immunohematology. We propose the use of optical tweezers to measure membrane viscosity, adhesion, zeta potential, and the double layer thickness of charges (DLT) formed around the cell in an electrolytic solution. For the membrane viscosity experiment, we trap a bead attached to RBCs and measure the force to slide one RBC over the other as a function of the velocity. Adhesion is quantified by displacing two RBCs apart until disagglutination. The DLT is measured using the force on the bead attached to a single RBC in response to an applied voltage. The zeta potential is obtained by measuring the terminal velocity after releasing the RBC from the trap at the last applied voltage. We believe that the methodology proposed here can provide information about agglutination, help to improve the tests usually performed in transfusion services, and be applied for zeta potential measurements in other samples.

Measurement of the electrophoretic mobility of sheep erythrocytes using microcapillary chips

Cell electrophoretic mobility (EPM) can be used to characterize individual cells. The purpose of this study is to establish reproducible and reliable cell EPM values obtained using microcapillary electrophoresis (microCE) chips. We studied cell electrophoresis on microCE chips through the comprehensive measurement of EPM and zeta potential. The inner wall of microchannels in microCE chips was coated with three kinds of reagents, namely bovine serum albumin (BSA), gelatin, and 2-methacryloyloxyethylphosphorylcholine (MPC) polymer to prevent nonspecific adhesion and interaction between cells and the inner wall. Electrophoresis was conducted in phosphate-buffered saline (pH 4-9) using erythrocytes extracted from sheep whole blood. Electroosmotic flow (EOF) mobility was measured using noncharged particles, and then the true EPM was calculated by subtracting the EOF mobility from the electromigration. MPC polymer coatings in microCE chips reduced the zeta potential of the inner wall and fully prevented nonspecific adhesion. EPM data obtained using microCE chips were almost the same and reproducible over a wide range of pH irrespective of the coating reagent used. In conclusion, reliability in the measurement of cell EPM using microCE chips was realized.

Preparation of red blood cell column for capillary electrochromatography

A column packed with red blood cells (RBCs) was prepared for electrochromatography as a separation and reaction column. RBCs were kept inside a piece of fused silica capillary tubing with 2% agarose gel. In the column, RBCs were uniformly distributed in the agarose gel matrix and their electrophoretic movements due to an applied voltage were suppressed well. The durability of the biological function of the column under applied voltage was about 1 h, although it could remain for 2-3 days without applied voltage. The column could not be used when hemolysis of the RBCs was observed in the column. When the developed "RBC-gel column" was used, both pyridoxamine and serotonin were converted to other compounds through their direct contact with RBCs.

Multistage magnetic and electrophoretic extraction of cells, particles and macromolecules

Improved techniques for separating cells, particles, and macromolecules (proteins) are increasingly important to biotechnology because separation is frequently the limiting factor for many biological processes. Manufacturers of new enzymes and pharmaceutical products require improved methods for recovering intact cells and intracellular products. Similarly isolation, purification, and concentration of many biomolecules produced in fermentation processes is extremely important. Often such downstream processing contributes a large portion of the product cost. In conventional methods like centrifugation and even modern methods like chromatography, scale-up problems are enormous, making them uneconomical and prohibitively expensive unless the product is of very high value. Therefore there has been a need for efficient and economical alternative approaches to bioseparation processes to eliminate, reduce, or facilitate solids handling. Magnetic and electric field assisted separations may hold considerable potential for providing a future major improvement in bioseparation technology. In the present review the merits and demerits of the existing methods are discussed. We present mainly our own research on the development of unified multistage extraction processes that are versatile enough to handle cells and particles as well as macromolecules as described below. We describe multistage methods, namely ADSEP (Advanced Separator), MAGSEP (Magnetic Separator), and ELECSEP (Electrophoretic Separator), for quantitatively separating cells, particles, and solutes by using magnetically and electrophoretically assisted extraction processes. To the best of our knowledge, multistage magnetic and electrophoretic separations have not been reported in the earlier literature. The theoretical underpinnings of these separations are crucial to their success and to the identification of their advantages over other separation processes in particular applications. Hence mathematical modeling is stressed here, presenting our own models while also reviewing models reported in the literature. We also present suggestions for future work while analyzing the scale-up and economic aspects of these extraction processes. Commercial uses of the magnetic and electrophoretic processes, having both ground- and space-based research elements, also are presented in this review.

Mammalian pituitary growth hormone: applications of free flow electrophoresis

We have used free flow electrophoresis (FFE) technology to study the electrophoretic behavior of growth hormone (GH) molecules, GH secretory granules and GH cell subpopulations contained in pituitary glands of humans and rodents. GH activities in different electrophoresis fractions were measured by immunoassay or bioassay, viz., measurement of chondrocyte proliferation in the tibial growth plate of the hypophysectomized rat. Using FFE we discovered a peptide in human post mortem pituitary tissue and cryopoor human plasma that is active in the tibial line bioassay, is inactive in a GH immunoassay, and is neither GH nor a GH fragment. This peptide, called tibial peptide, has high anodal mobility and is readily separable from GH by FFE. Its molecular mass is approximately 5 kD. It is particularly rich in glycine. A partial amino acid sequence (residues 9-25) in the middle region of the peptide shows that 9 of the 16 residues are nonpolar. On the basis of results from other FFE experiments, using either GH-containing secretory granules or GH-producing cells, we believe that the peptide is stored within the secretion granule of a subpopulation of GH cells. On the basis of recent information elucidating the role of C peptide contained in the insulin storage granule of the pancreatic cell, we propose that the tibial peptide serves a similar role in the GH cell. Thus, not only may tibial peptide aid in proper alignment of disulfide bonds between GH monomers in the secretory granule, but, like the C peptide, it also appears to have biologic activity in its own right.

Advances in cell separation: recent developments in counterflow centrifugal elutriation and continuous flow cell separation

Cell separation by counterflow centrifugal elutriation (CCE) or free flow electrophoresis (FFE) is performed at lower frequency than cell cloning and antibody-dependent, magnetic or fluorescence-activated cell sorting. Nevertheless, numerous recent publications confirmed that these physical cell separation methods that do not include cell labeling or cell transformation steps, may be most useful for some applications. CCE and FFE have proved to be valuable tools, if homogeneous populations of normal healthy untransformed cells are required for answering scientific questions or for clinical transplantation and cells cannot be labeled by antibodies, because suitable antibodies are not available or because antibody binding to a cell surface would induce the cell reaction which should be investigated on purified cells or because antibodies bound to the surface hamper the use of the isolated cells. In addition, the methods are helpful for studying the biological reasons for, or effects of, changes in cell size and cellular negative surface charge density. Although the value of the methods was confirmed in recent years by a considerable number of important scientific results, activities to further develop and improve the instruments have, unfortunately, declined.

High performance density gradient electrophoresis of subcellular organelles, protein complexes and proteins

A density gradient electrophoresis (DGE) apparatus (2.2 x, 14 cm) was constructed for the rapid separation of milligram quantities of proteins. By using binary buffers according to Bier (Electrophoresis 1993, 14, 1011-1018) proteins were rate-zonally separated in less than 60 min. Acidic proteins were separated in a pH 8.6, 56 microS/cm buffer, and basic proteins in a pH 5.4, 76 microS/cm buffer. Thus the A (pI 5.15) and B (pI 5.30) forms of beta-lactoglobulin as well as the sialylated glycoforms of apotransferrin were well separated at pH 8.6. The isoforms of myoglobin (pI 6.9 and 7.35, respectively), RNAse A (pI 9.45) and cytochrome c (pI 10.0) and lysozyme (pI 11) were separated at pH 5.4 within 80 min. On a 7 cm DGE column, subcellular organelles derived from HeLa cells were separated in standard electrophoresis buffer (655 microS/cm) for 90 min at 10 mA. Using a new low conductivity buffer (193 microS/cm) 20 min was sufficient to separate late endosomes, lysosomes, endoplasmic reticulum, early endosomes, plasma membrane, clathrin-coated pits, proteasomes, and clathrin-coated vesicles within a single run directly from a postnuclear supernatant.

Cellular electrophoretic mobility data: a first approach to a database

Cellular electrophoretic mobility values of 288 types of eucaryotic cells were collected from literature published worldwide by a series of authors during the past forty years and arranged in a list. This list contains well-known recent electrophoretic results and also data that cannot be found anymore with modern literature retrieval systems. It will be a valuable help for scientists trying to purify cell populations. In addition, it confirms the observation that most eucaryotic cells have very similar electrophoretic mobilities, ranging from 40% above to 50% below the electrophoretic mobility of human erythrocytes, and thus reinforces the suggestion that electrophoretic mobilities of eucaryotic cells are subjected to strong biological controls.

Bioprocessing in microgravity: applications of continuous flow electrophoresis to rat anterior pituitary particles

In this report we describe the results of a continuous flow electrophoresis (CFE) experiment done on STS-65 in which we tested the idea that intracellular growth hormone (GH) particles contained in a cell lysate prepared from cultured rat anterior pituitary cells in microgravity might have different electrophoretic mobilities from those in a synchronous ground control cell lysate. Collectively, the results suggested that CFE processing in microgravity was better than on earth; more sample could be processed/time (6 x) and more variant forms of GH molecules could be resolved as well. We had also hoped to carry out a pituitary cell CFE experiment, but failure of the hardware required that the actual cell electrophoresis trials be done on earth shortly after Shuttle landing. Data from these experiments showed that space-flown cells possessed a higher electrophoretic mobility than ground control cells, thereby offering evidence for the idea that exposure of cultured cells to microgravity can change their net surface charge-density especially when the cells are fed. Collectively, the results from this pituitary cell experiment document the advantage of using coupled cell culture and CFE techniques in the microgravity environment.

Further analyses of human kidney cell populations separated on the Space Shuttle

Cultured human embryonic kidney cells were separated into electrophoretic subpopulations in laboratory experiments and in two separation experiments on the STS-8 (Challenger) Space Shuttle flight using the mid-deck Continuous Flow Electrophoretic Separator (CFES). Populations of cells from each fraction were cultured for the lifetime of the cells, and supernatant medium was withdrawn and replaced at 4-day intervals. Withdrawn medium was frozen at -120 degrees C for subsequent analysis. Enzyme assays, antibodies and gel electrophoresis were used as analytical tools for the detection and quantitation of plasminogen activators in these samples. These assays of frozen culture supernatant fluids confirmed the electrophoretic separation of plasminogen-activator producing cells from non-producing cells, the isolation of cells capable of sustained production, and the separation of cells that produce different plasminogen activators from one another.

A miniaturized fibrinolytic assay for plasminogen activators

This report describes a micro-clot lysis assay (MCLA) for evaluating fibrinolytic activity of plasminogen activators (PA). Fibrin clots were formed in wells of microtiter plates. Lysis of the clots by PA, indicated by change in turbidity (optical density, OD), was monitored with a microplate reader at five minutes intervals. Log-log plots of PA dilution versus endpoint, the time at which the OD value was halfway between the maximum and minimum value for each well, were linear over a broad range of PA concentrations (2-200 International units/ml). The MCLA is a modification and miniaturization of well established fibrinolytic methods. The significant practical advantages of the MCLA are that it is a simple, relatively sensitive, non-radioactive, quantitative, kinetic, fibrinolytic micro-technique which can be automated.

The pituitary: aging and spaceflown rats

Decrements in growth hormone (GH) release we observed in two spaceflight experiments and four tail-suspended rat studies mimic age-associated changes in the mammalian pituitary GH system seen by Meites and others. The spaceflight data suggest that formation of high molecular weight bioactive disulfide-linked aggregates of the 20 and 22K monomeric GH forms may be reduced in microgravity, thereby, reducing target tissue activity. Correlative studies to confirm spaceflight as a model for pituitary GH system aging should include: 1) investigation of mechanisms of intracellular hormone packaging, 2) consequences to biological activity of the hormone molecule, and 3) study of intracellular microtubule dynamics.

Separation of rat pituitary secretory granules by continuous flow electrophoresis

The separation of growth hormone-containing cytoplasmic secretory granules from the rat pituitary gland by continuous flow electrophoresis is described. The results are consistent with the hypothesis that granule subpopulations can be separated due to differences in surface charge; these, in turn, may be related to the oligomeric state of the hormone.

The development of recycle zone electrophoresis

Milan Bier's contributions to preparative electrophoresis and, in particular, his work in "recycling", have had an enormous impact on the development of scaling strategies for continuous flow electrophoresis. This paper reviews my early work on the theory of recycle applied to zone electrophoresis and reports the results of several recent experiments in which proteins were purified from complex feed mixtures using recycle zone electrophoresis.

Comparative studies of recycling isoelectric focusing and continuous flow electrophoresis: separation of proteins with minor charge differences

Continuous flow zone electrophoresis (CFE) and recycling isoelectric focusing (RIEF) are two of the alternative formats for fluid phase preparative isolation of biological products in liquid separation media. The McDonnell Douglas CFE system has been used for both ground-based and microgravity separations. The ground-based McDonnell Douglas CFE and RIEF were compared for the ability to resolve mixtures of proteins with known charge differences. Mixtures of 1) cytochrome c, myoglobin, and ovalbumin or 2) beta-lactoglobulin and ovalbumin were used to evaluate the resolving capabilities of CFE and RIEF. Following separation, fractions were analyzed by determining absorbance at 280 nm and by analytical isoelectric focusing (IEF) using Coomassie Brilliant Blue or silver staining to detect focused proteins. Both CFE and RIEF apparently separated the components of both mixtures into individual peaks, separated by fractions which contained little or no detectable protein. Coomassie-stained analytical IEF gels supported this finding. However, when separated proteins were analyzed by silver staining of the analytical gels, the separation of ovalbumin from beta-lactoglobulin by CFE was not complete. Ovalbumin was free of beta-lactoglobulin but beta-lactoglobulin was contaminated by trace amounts of ovalbumin. RIEF clearly separated each protein with no detectable contamination. These data demonstrate the superiority of RIEF over CFE for resolution of protein mixtures having only minor charge differences. RIEF may be more efficient due to the documented electrodissociation of noncovalent protein:protein complexes which occurs during RIEF separations.

Free-flow electrophoresis under microgravity: evidence for enhanced resolution of cell separation

A mixture of fixed rabbit, guinea pig and rat erythrocytes, suspended in a relatively conductive solution, was separated by means of continuous free flow electrophoresis (CFFE) under 1 g- and microgram- conditions using a specially designed electrophoretic module. Short duration microgram conditions were realized on board a sounding rocket. Due to the energy input and the associated thermal convection a separation of the three differently charged cell types in distinct peaks was not possible under 1 g-conditions as shown by reference experiments on the ground before launch. In contrast to the poor resolution under 1 g-conditions, clear separation of the cell mixture could be recorded after lift-off of the rocket under microgram-conditions. Repeated measurements demonstrated that the separation profile was completely stable during the entire microgram-phase of about 6 min. Since the CFFE experiment in space was an exact replica of the ground reference experiments, the results demonstrated unambiguously the potential of CFFE for cell separation under microgram-conditions in media of high ionic strength.

Free flow electrophoresis in space shuttle program (Biotex)

In the space shuttle program free flow electrophoresis will be applied for separation of proteins, biopolymers and cells. Proteins are to be separated according to the "Feldsprung-Gradienten" procedure by Prof. H. Wagner, University of Saarbruecken, biopolymers are to be separated by the isotachophoresis technique by Prof. Schmitz, University of Muenster and we intend to separate cells in order to increase the efficiency of recovery of hybrid cells after electrofusion performed under microgravity in collaboration with Prof. U. Zimmermann, University of Wuerzburg. There are supposed two ways for reaching this goal: 1) Enrichment of cells before electrofusion may enhance the probability that the cells of interest are immortalized. 2) Separation of cells after electrofusion may help to clone the hybrid cells of interest. Under microgravity, the combination of improved electrophoresis with higher electrofusion rates may provide new possibilities for immortalization of cells. This may be a new way to obtain cellular products, which are physiologically glycosylated.