Dye with low specificity to nucleotide sequences of DNA: use for assessing the quantity of oligonucleotides, immobilized in cells of biological microchips

To assess the DNA amount in samples (e.g., in biological microchip gel pads) by means of fluorescent dyes, one should use the dyes whose fluorescence weakly depends on DNA composition and structure. With the ImD-310 dye created for this purpose, we have analyzed the staining of single- and double-stranded oligo- and polynucleotides of different nucleotide composition, length, and concentration both in solution and being immobilized in biological microchip gel pads. It turned out that ImD-310 has no pronounced specificity to the single- and double-stranded nucleotide sequences, while the intensity of fluorescence for the dye complexes with d(A)8, d(T)8, d(C)8, and d(G)8 at high temperatures (50 degrees C) differs by less than 25%. A linear correlation has been established between the intensity of fluorescence and the amount of oligonucleotides immobilized on a biological microchip. The plots of the intensity of fluorescence against the concentration of NaCl and the temperature were obtained. By using a generic microchip containing all 4096 hexamer oligonucleotides, it has been determined that the dye has no distinct specificity to any certain motifs of the nucleotide sequence. Thus, ImD-310 may serve as an efficient fluorescent probe to quickly estimate the amount of oligonucleotides immobilized in a microchip, in an electrophoretic gel, etc.     

A Fluorescent Dye with Low Specificity to DNA Nucleotide Sequences: Quantitative Assessment of Oligonucleotides Immobilized in Microchip Gel Pads

To assess the DNA amount in samples (e.g., in biological microchip gel pads) by means of fluorescent dyes, one should use the dyes whose fluorescence weakly depends on DNA composition and structure. With the ImD-310 dye created for this purpose, we have analyzed the staining of single- and double-stranded oligo- and polynucleotides of different nucleotide composition, length, and concentration both in solution and being immobilized in biological microchip gel pads. It turned out that ImD-310 has no pronounced specificity to the single- and double-stranded nucleotide sequences, while the intensity of fluorescence for the dye complexes with d(A)₈, d(T)₈, d(C)₈, and d(G)₈ at high temperatures (50°C) differs by less than 25%. A linear correlation has been established between the intensity of fluorescence and the amount of oligonucleotides immobilized on a biological microchip. The plots of the intensity of fluorescence against the concentration of NaCl and the temperature were obtained. By using a generic microchip containing all 4096 hexamer oligonucleotides, it has been determined that the dye has no distinct specificity to any certain motifs of the nucleotide sequence. Thus, ImD-310 may serve as an efficient fluorescent probe to quickly estimate the amount of oligonucleotides immobilized in a microchip, in an electrophoretic gel, etc.     

Quantitative immunoassay of biotoxins on hydrogel-based protein microchips

Three-dimensional gel-based microchips with immobilized proteins were used for quantitative immunoassay of a series of plant (ricin and viscumin) and bacterial (staphylococcal enterotoxin B, tetanus and diphtheria toxins, and lethal factor of anthrax) toxins. It was shown that different types of immunoassays (direct, competitive, and sandwich type) could be carried out on gel microchips. As shown by confocal microscope studies, antigen-antibody interactions involving the formation of tertiary antibody-antigen-antibody complex occur in the whole volume of microchip gel elements. Sandwich assay on microchips with immobilized antibodies provided the highest sensitivity of detection (0.1 ng/ml for ricin). Antibodies labeled with fluorescent dyes, horseradish peroxidase conjugates, or biotinylated antibodies with subsequent treatment with labeled avidin were used as developing antibodies. The results of immunoassays were recorded using fluorescence, chemiluminescence, or matrix-assisted laser desorption ionization mass spectrometry directly from microchip gel elements. Gel microchips with immobilized capture antibodies were used to analyze the sample simultaneously for the presence of all six biotoxins with the same sensitivity as that for any single toxin.     

Alginate gel microchip for real-time monitoring of intracellular processes in bacterial and yeast cells

A method of alginate-based hydrogel cell microchip manufacturing is proposed. The development of mild conditions for cell immobilization in microvolumes of non-toxic alginate gel allows extending the range of microorganisms used. Different approaches to cell analysis using microchip have been approved in pilot studies. By the example of Escherichia coli, Bordetella bronchiseptica and Saccharomyces cerevisiae it is shown that cell microchip can be successfully applied for monitoring of nucleic acid and protein synthesis in growing cells simultaneously using two fluorescent dyes. The influence of chloramphenicol on the nucleic acids and protein synthesis in five bacterial strains has been studied on the microchip. The microchip was also applied for the analysis of inducible fluorescent protein EGFP synthesis in E. coli cells, the correlation between the level of EGFP synthesis and concentration of the inductor in the medium has been established.     

PCR amplification on a microarray of gel-immobilized oligonucleotides: detection of bacterial toxin- and drug-resistant genes and their mutations

PCR amplification on a microarray of gel-immobilized primers (microchip) has been developed. One of a pair of PCR primers was immobilized inside a separate microchip polyacrylamide porous gel pad of 0.1 x 0.1 x 0.02 (or 0.04) micron in size and 0.2 (or 0.4) nL in volume. The amplification was carried out simultaneously both in solution covering the microchip array and inside gel pads. Each gel pad contained the immobilized forward primers, while the fluorescently labeled reverse primers, as well as all components of the amplification reaction, diffused into the gel pads from the solution. To increase the amplification efficiency, the forward primers were also added into the solution. The kinetics of amplification was measured in real time in parallel for all gel pads with a fluorescent microscope equipped with a charge-coupled device (CCD) camera. The accuracy of the amplification was assessed by using the melting curves obtained for the duplexes formed by the labeled amplification product and the gel-immobilized primers during the amplification process; alternatively, the duplexes were produced by hybridization of the extended immobilized primers with labeled oligonucleotide probes. The on-chip amplification was applied to detect the anthrax toxin genes and the plasmid-borne beta-lactamase gene responsible for bacterial ampicillin resistance. The allele-specific type of PCR amplification was used to identify the Shiga toxin gene and discriminate it from the Shiga-like one. The genomic mutations responsible for rifampicin resistance of the Mycobacterium tuberculosis strains were detected by the same type of PCR amplification of the rpoB gene fragment isolated from sputum of tuberculosis patients. The on-chip PCR amplification has been shown to be a rapid, inexpensive and powerful tool to test genes responsible for bacterial toxin production and drug resistance, as well as to reveal point nucleotide mutations.     

Parallel thermodynamic analysis of duplexes on oligodeoxyribonucleotide microchips.

A microchip method has been developed for massive and parallel thermodynamic analyses of DNA duplexes. Fluorescently labeled oligonucleotides were hybridized with oligonucleotides immobilized in the 100 x 100 x 20 mum gel pads of the microchips. The equilibrium melting curves for all microchip duplexes were measured in real time in parallel for all microchip duplexes. Thermodynamic data for perfect and mismatched duplexes that were obtained using the microchip method directly correlated with data obtained in solution. Fluorescent labels or longer linkers between the gel and the oligonucleotides appeared to have no significant effect on duplex stability. Extending the immobilized oligonucleotides with a four-base mixture from the 3'-end or one or two universal bases (5-nitroindole) from the 3'- and/or 5'-end increased the stabilities of their duplexes. These extensions were applied to increase the stabilities of the duplexes formed with short oligonucleotides in microchips, to significantly lessen the differences in melting curves of the AT- and GC-rich duplexes, and to improve discrimination of perfect duplexes from those containing poorly recognized terminal mismatches. This study explored a way to increase the efficiency of sequencing by hybridization on oligonucleotide microchips.     

Biological microchips with hydrogel-immobilized nucleic acids,proteins, and other compounds: properties and applications in genomics

The MAGIChip (MicroArrays of Gel-Immobilized Compounds on a chip) consists of an array of hydrophilic gel pads fixed on a hydrophobic glass surface. These pads of several picoliters to several nanoliters in volume contain the gel-immobilized nucleic acids, proteins, and other compounds, as well as live cells. They are used to conduct chemical and enzymatic reactions with the immobilized compounds or samples bound to them. In the latter case, nucleic acid fragments can be hybridized, modified, and fractionated within the gel pads. The main procedures required to analyze nucleic acid sequences (PCR, detachment of primers and PCR-amplified products from a substrate, hybridization, ligation, and others) can be also performed within the microchip pads. A flexible, multipurpose, and inexpensive system has been developed to register the processes proceeding on a microchip. The system provides unique possibilities for research and biomedical applications, allowing one to register both equilibrium states and the course of reaction in real time. The system is applied to analyze both kinetic and thermodynamic characteristics of molecular interaction in the duplexes formed between nucleic acids and the probes immobilized within the microchip gel pads. Owing to the effect of stacking interaction of nucleic acids, the use of short oligonucleotides extends the possibilities of microchips for analysis of nucleic acid sequences, allowing one to employ the MALDI-TOF mass spectrometry to analyze the hybridization data. The specialized MAGIChips has been successfully applied to reveal single nucleotide polymorphism of many biologically significant genes, to identify bacteria and viruses, to detect toxins and characterize the genes of pathogenic bacteria responsible for drug resistance, and to study translocations in the human genome. On the basis of the MAGIChip, the protein microchips have been created, containing the immobilized antibodies, antigens, enzymes, and many other substances, as well as the microchips with the gel-immobilized live cells.     

Biological Microchips with Hydrogel-Immobilized Nucleic Acids,Proteins, and Other Compounds: Properties and Applications in Genomics

The MAGIChip (MicroArrays of Gel-Immobilized Compounds on a chip) consists of an array of hydrophilic gel pads fixed on a hydrophobic glass surface. These pads of several picoliters to several nanoliters in volume contain gel-immobilized nucleic acids, proteins, and other compounds, as well as live cells. They are used to conduct chemical and enzymatic reactions with the immobilized compounds or samples bound to them. In the latter case, nucleic acid fragments can be hybridized, modified, and fractionated within the gel pads. The main procedures required to analyze nucleic acid sequences (PCR, detachment of primers and PCR-amplified products from a substrate, hybridization, ligation, and others) can be also performed within the microchip pads. A flexible, multipurpose, and inexpensive system has been developed to register the processes on a microchip. The system provides unique possibilities for research and biomedical applications, allowing one to register both equilibrium states and the course of reaction in real time. The system is applied to analyze both kinetic and thermodynamic characteristics of molecular interaction in the duplexes formed between nucleic acids and the probes immobilized within the microchip gel pads. Owing to the effect of stacking interaction of nucleic acids, the use of short oligonucleotides extends the possibilities of microchips for analysis of nucleic acid sequences, allowing one to employ the MALDI-TOF mass spectrometry to analyze the hybridization data. The specialized MAGIChips has been successfully applied to reveal single-nucleotide polymorphism of many biologically significant genes, to identify bacteria and viruses, to detect toxins and characterize the genes of pathogenic bacteria responsible for drug resistance, and to study translocations in the human genome. On the basis of the MAGIChip, protein microchips have been created, containing immobilized antibodies, antigens, enzymes, and many other substances, as well as microchips with gel-immobilized live cells.     

Massive parallel analysis of the binding specificity of histone-like protein HU to single- and double-stranded DNA with generic oligodeoxyribonucleotide microchips

A generic hexadeoxyribonucleotide microchip has been applied to test the DNA-binding properties of HU histone-like bacterial protein, which is known to have a low sequence specificity. All 4096 hexamers flanked within 8mers by degenerate bases at both the 3′- and 5′-ends were immobilized within the 100 × 100 × 20 mm polyacrylamide gel pads of the microchip. Single-stranded immobilized oligonucleotides were converted in some experiments to the double-stranded form by hybridization with a specified mixture of 8mers. The DNA interaction with HU was characterized by three type of measurements: (i) binding of FITC-labeled HU to microchip oligonucleotides; (ii) melting curves of complexes of labeled HU with single-stranded microchip oligonucleotides; (iii) the effect of HU binding on melting curves of microchip double-stranded DNA labeled with another fluorescent dye, Texas Red. Large numbers of measurements of these parameters were carried out in parallel for all or many generic microchip elements in real time with a multi-wavelength fluorescence microscope. Statistical analysis of these data suggests some preference for HU binding to G/C-rich single-stranded oligonucleotides. HU complexes with double-stranded microchip 8mers can be divided into two groups in which HU binding either increased the melting temperature (T_m) of duplexes or decreased it. The stabilized duplexes showed some preference for presence of the sequence motifs AAG, AGA and AAGA. In the second type of complex, enriched with A/T base pairs, the destabilization effect was higher for longer stretches of A/T duplexes. Binding of HU to labeled duplexes in the second type of complex caused some decrease in fluorescence. This decrease also correlates with the higher A/T content and lower T_m. The results demonstrate that generic microchips could be an efficient approach in analysis of sequence specificity of proteins.     

Polymorphism analysis and gene detection by minisequencing on an array of gel-immobilized primers.

Two procedures, multibase and multiprimer, have been developed for single nucleotide extension of primers immobilized within polyacrylamide gel pads on a microchip. In the multibase assay, a primer is next to a polymorphic nucleotide; the nucleotide is identified by the specificity with which the primer incorporates fluorescently labeled dideoxyribo-nucleoside triphosphates. In the multiprimer assay, several primers containing different 3'-terminal nucleotides overlapping the variable nucleotide in DNA are used. The polymorphic nucleotide is identified according to the primer that is extended. The methods were compared for diagnosis of beta-thalassemia mutations. Isothermal amplification of the fluorescent signal was achieved by performing both assays at elevated temperature. Anthrax toxin genes were identified in a model system using this amplification method.     

Protein microchips: use for immunoassay and enzymatic reactions

Different proteins such as antibodies, antigens, and enzymes were immobilized within the 100 x 100 x 20-microm gel pads of protein microchips. A modified polyacrylamide gel has been developed to accommodate proteins of a size up to 400,000 daltons. Electrophoresis in the microchip reaction chamber speeded up antigen-antibody interactions within the gel. Protein microchips were used in immunoassays for detection of antigens or antibodies, as well as to carry out enzymatic reactions and to measure their kinetics in the absence or presence of an inhibitor. A protein microchip can be used several times in different immunoassays and enzymatic kinetic measurements.     

Integration of multiple PCR amplifications and DNA mutation analyses by using oligonucleotide microchip

We have developed a method for parallel independent on-chip amplification and the following sequence variation analysis of multiple DNA regions directly using microchip with an array of nanoliter gel pads containing specific sets of tethered primers. The method has three key features. First, DNA to be amplified is enriched at gel pads by its hybridization with immobilized primers. Second, different sets of specific primers are immobilized within various gel pads, and primers are detached within gel pads just before polymerase chain reaction to enhance the amplification. A gel pad may contain an additional permanently immobilized dormant primer that is activated to carry out the allele-specific primer extension reaction to detect mutations. Third, multiple polymerase chain reactions are confined within nanoliter gel pads covered and separated from each other with mineral oil. The method was applied to simultaneously identify several abundant drug-resistant mutations in three genes of Mycobacterium tuberculosis.     

Gel-Based Microchips: History and Prospects

The review describes the history of formation and development of the microchip technology and its role in the human genome project in Russia. The main accent was done on the three-dimensional gel-based microchips developed at the Center of Biological Microchips headed by A.D. Mirzabekov since 1988. The gel-based chips of the last generation, IMAGE chips (Immobilized Micro Array of Gel Elements), have a number of advantages over the previous models. The microchips are manufactured by photoinitiated copolymerization of gel components and immobilized molecules (DNA, proteins, and ligands). This ensures an even distribution of the immobilized probe throughout the microchip gel element with a high yield (about 50% for oligonucleotides). The use of methacrylamide as a main component of the polymerization mixture resulted in a substantial increase of gel porosity without affecting its mechanical properties and stability; this allowed one to work with the DNA fragments of up to 500 nt in length, as well as with quite large protein molecules. At present, the gel-based microchips are widely applied to solve different problems. The generic microchips containing a complete set of possible hexanucleotides are used to reveal the DNA motifs binding with different proteins and to study the DNA–protein interactions. The oligonucleotide microchips are a cheap and reliable diagnostic tool designed for mass application. Biochips have been developed for identification of the tuberculosis pathogen and its antibiotic-resistant forms; of orthopoxviruses, including the smallpox virus; of the anthrax pathogen; and chromosomal rearrangements in leukemia patients. The protein microchips can be adapted for further use in proteo-mics. Bacterial and yeast cells were also immobilized in the gel, maintaining their viability, which opens a wide potential for creating biosensors on the basis of microchips.     

Microchips based on three dimensional gel cells: history and perspective

The review describes the history of creation and development of the microchip technology and its role in the human genome project in Russia. The emphasis is placed on the three-dimensional gel-based microchips developed at the Center of Biological Microchips headed by A.D. Mirzabekov since 1988. The gel-based chips of the last generation, IMAGE chips (Immobilized Micro Array of Gel Elements), have a number of advantages over the previous versions. The microchips are manufactured by photo-initiated copolymerization of gel components and immobilized molecules (DNA, proteins, and ligands). This ensures an even distribution of the immobilized probe throughout the microchip gel element with a high yield (about 50% for oligonucleotides). The use of methacrylamide as a main component of the polymerization mixture resulted in a substantial increase of gel porosity without affecting its mechanical strength and stability, which allowed one to work with the DNA fragments of up to 500 nt in length, as well as with rather large protein molecules. At present, the gel-based microchips are widely applied to address different problems. The generic microchips containing a complete set of possible hexanucleotides are used to reveal the DNA motifs binding with different proteins and to study the DNA-protein interactions. The oligonucleotide microchips are a cheap and reliable tool of diagnostics designed for mass application. Biochips have been developed for identification of the tuberculosis pathogen and its antibiotic-resistant forms; for diagnostics of orthopoxviruses, including the smallpox virus; for diagnostics of the anthrax pathogen; and for identification of chromosomal rearrangements in leukemia patients. The protein microchips can be adapted for further use in proteomics. Bacterial and yeast cells were also immobilized in the gel, maintaining their viability, which open a wide potential for creation biosensors on the basis of microchips.     

Analysis of perfect and mismatched DNA duplexes by a generic hexanucleotide microchip

The thermodynamic analysis was done for the duplexes formed by fluorescently labeled oligonucleotide targets on a genetic hexanucleotide microchip. All 4096 different hexanucleotide chains were immobilized as probes in individual gel pads of the microchip. To strengthen the hybridization, each hexamer was extended at both ends by one nucleotide from the equimolar mixture of all four nucleotides to serve as nonselective linkers. It has been shown that the melting curves for oligonucleotide duplexes formed on the microchip and in a solution are quite similar. The influence of ionic surrounding has been studied in terms of the hybridization efficiency and discrimination between the mismatched and perfect duplexes. Different approaches have been tested to compensate the dependence of duplex stability on the GC content. It has been demonstrated that the use of chaotropic agents, addition of nonlabeled GC-rich competitor oligonucleotides, as well as creation of a temperature gradient along the microchip reproducing the distribution of melting temperatures, efficiently level out the AT/GC differences. The use of tetramethylammonium chloride for the same purpose was accompanied by weakening to some extent the discrimination between the mismatched duplexes and the perfect ones.     

Analysis of Perfect and Mismatched DNA Duplexes with a Generic Hexanucleotide Microchip

Thermodynamic analysis was performed for the duplexes formed by fluorescently labeled oligonucleotide targets on a generic hexanucleotide microchip. All 4096 different hexanucleotide chains were immobilized as probes in individual gel pads of the microchip. To strengthen the hybridization, each hexamer was extended at both ends by one nucleotide from the equimolar mixture of all four nucleotides to serve as nonselective linkers. It has been shown that the melting curves for oligonucleotide duplexes formed on the microchip and in a solution are quite similar. The influence of ionic surrounding has been studied in terms of the hybridization efficiency and discrimination between the mismatched and perfect duplexes. Different approaches have been tested to compensate the dependence of duplex stability on the GC content. It has been demonstrated that the use of chaotropic agents, addition of nonlabeled GC-rich competitor oligonucleotides, as well as creation of a temperature gradient along the microchip reproducing the distribution of melting temperatures, efficiently level out the AT/GC differences. The use of tetramethylammonium chloride for the same purpose was accompanied by weakening to some extent the discrimination between the mismatched duplexes and the perfect ones.     

Phospholipase A(2)-catalyzed membrane leakage studied by immobilized liposome chromatography with online fluorescent detection

Unilamellar liposomes composed of phosphatidylcholine with an entrapped self-quenching fluorescent dye, calcein, were immobilized in chromatographic gel beads by avidin-biotin binding. Bee venom phospholipase A(2) (PLA(2)) was applied in a small amount onto the immobilized liposome column. The release of calcein from the immobilized liposomes resulting from the catalyzed hydrolysis of the phospholipids was detected online by immobilized liposome chromatography (ILC) using a flow fluorescent detector. The PLA(2)-catalyzed membrane leakage of the immobilized liposomes as studied with ILC was found to be affected by the gel pore size used for immobilization, by liposome size, and as expected by the concentration of calcium, but was unaffected by the flow rate of ILC. The largest PLA(2)-induced calcein release from the liposome column was detected on large unilamellar liposomes immobilized on TSK G6000PW or Sephacryl S-1000 gel in the presence of 1 mM Ca(2+) in the aqueous mobile phase. Comparison with the PLA(2)-catalyzed membrane leakage in free liposome suspensions, we conclude that the fluorescent leakage from liposomes hydrolyzed by PLA(2) can be rapidly and sensitively detected by ILC runs using large amount of immobilized liposomes with entrapped fluorescent dye.     

DNA sequencing by hybridization to microchip octa-and decanucleotides extended by stacked pentanucleotides.

The efficiency of sequencing by hybridization to an oligonucleotide microchip grows with an increase in the number and in the length of the oligonucleotides; however, such increases raise enormously the complexity of the microchip and decrease the accuracy of hybridization. We have been developing the technique of contiguous stacking hybridization (CSH) to circumvent these shortcomings. Stacking interactions between adjacent bases of two oligonucleotides stabilize their contiguous duplex with DNA. The use of such stacking increases the effective length of microchip oligonucleotides, enhances sequencing accuracy and allows the sequencing of longer DNA. The effects of mismatches, base composition, length and other factors on the stacking are evaluated. Contiguous stacking hybridization of DNA with immobilized 8mers and one or two 5mers labeled with two different fluorescent dyes increases the effective length of sequencing oligonucleotides from 8 to 13 and 18 bases, respectively. The incorporation of all four bases or 5-nitroindole as a universal base into different positions of the 5mers permitted a decrease in the number of additional rounds of hybridization. Contiguous stacking hybridization appears to be a promising approach to significantly increasing the efficiency of sequencing by hybridization.     

An RNA microchip containing immobilized oligoribonucleotides with protective groups at 2'-O-positions

To analyze RNA interactions with RNA binding molecules an RNA microchip containing immobilized oligoribonucleotides with protective groups [t-butyldimethylsilyl (tBDMS)] at 2'-O- positions was developed. The oligonucleotides were immobilized within three-dimensional (3-D) hydrogel pads fixed on a glass support. The protective groups preserved the oligoribonucleodes from degradation and were suitable to be removed directly on the microchip when needed, right before its use. These immobilized, deprotected oligoribonucleotides were tested for their interaction with afluorescently labeled oligodeoxyribonucleotide and analyzed for their availability to be cleaved enzymatically by the RNase binase. Stability of tBDMS-protected immobilized oligoribonucleotides after 2.5 years of storage as well as after direct RNase action was also tested. Melting curves of short RNA/DNA hybrids that had formed into gel pads of the microchip were found to exhibit clearly defined S-like shapes, with the melting temperatures in full accordance with those theoretically predicted for the same ionic strength. This approach, based on keeping the protective groups attached to oligoribonucleotides, can be applied for manufacturing any RNA microchips containing immobilized oligoribonucleotides, including microchips with two-dimensional (2-D) features. These RNA microchips can be used to measure thermodynamic parameters of RNA/RNA or RNA/DNA duplexes as well as to study ligand- or protein-RNA interactions.     

Changes in monoclonal antibody productivity of recombinant BHK cells immobilized in collagen gel particles

Animal cell perfusion high density culture is often adopted for the production of biologicals in industry. In high density culture sometimes the productivity of biologicals has been found to be enhanced. Especially in immobilized animal cell culture, significant increase in the productivity has been reported. We have found that the specific monoclonal antibody (MAb) productivity of an immobilized hybridoma cell is enhanced more than double. Several examples of enhancing productivities have been also shown by collagen immobilized cells. Immobilized cells involve some different points from non-immobilized cells in high density culture: In immobilized culture, some cells are contacted together, resulting in locally much higher cell concentration more than 10⁸ cells/ml. Information originating from a cell can be easily transduced to the others in immobilized culture because the distance between cells is much nearer. Here we have performed collagen gel immobilized culture of recombinant BHK cells which produce a human IgG monoclonal antibody in a protein-free medium for more than three months. In this high density culture a stabilized monoclonal antibody production was found with around 8 times higher specific monoclonal antibody productivity compared with that in a batch serum containing culture. No higher MAb productivity was observed using a conditioned medium which was obtained from the high density culture, indicating that no components secreted from the immobilized cells work for enhancing monoclonal antibody production. The MAb productivity by the non-immobilized cells obtained by dissolving collagen using a collagenase gradually decreased and returned to the original level in the batch culture using a fresh medium. This suggests that the direct contact of the cells or a very close distance between the cells has something to do with the enhancement of the MAb productivity, and the higher productivity is kept for a while in each cell after they are drawn apart.