Oriented covalent immobilization of antibodies on physically inert and hydrophilic support surfaces through their glycosidic chains

Immobilization of antibodies by their oxidized sugar chain on aminated supports is a very efficient methodology to have a properly oriented antibody. However, these supports may behave as anionic exchangers, producing the unspecific adsorption of other proteins and reducing the selectivity of the system. To overcome this problem, we have proposed two solutions based in tailor-made support surfaces to immobilize antihorseradish peroxidase (HRP). The first solution was the use of supports having a very low amount of amino groups. These amino groups need to be very reactive with the aldehyde groups generated in the protein sugar chains to be efficient. Using supports having 7 micromol EDA/g (e.g., ethylenediamine modified glyoxyl-agarose), the antibody may be immobilized, keeping over 90% of the anti-HRP functionality. Second, by mixing amino groups and carboxylic groups, a neutral surface of the support has been generated. Again, this support has been unable to adsorb proteins while oxidized anti-HRP could be immobilized, giving functional anti-HRP antibodies. Both preparations retained 100% functionality after 2 months of storage at 4 degrees C. This way, the tailoring of the support surfaces has permitted solving some limitations of the immobilization of sugar-chain oxidized antibodies on primary amino supports.     

Use of dextrans as long and hydrophilic spacer arms to improve the performance of immobilized proteins acting on macromolecules

New dextran-agarose supports, suitable for covalent immobilization of enzymes and proteins acting on macromolecular substrates, were prepared. The thick internal fibers of agarose gels were covered by a low-density layer of long, flexible, hydrophilic, and inert dextran molecules. Rennin and protein A were immobilized on these novel supports and the resulting derivatives exhibited a very high capacity for biological recognition of soluble macromolecular substrates. Caseinolytic activity of this immobilized enzyme was 15-fold higher than activity of directly immobilized rennin, through short spacer arms, on agarose gels. Similarly, the new derivatives of immobilized protein A were able to adsorb up to 2 molecules of immunoglobulin per each molecule of immobilized protein A. When the immobilized proteins were secluded away from the support surface by using these new long and hydrophilic spacer arms, they exhibit minimal steric hindrances that could be promoted by the proximity of the support surface.     

Influence of a poly-ethylene glycol spacer on antigen capture by immobilized antibodies

The use of spacers to distance an immobilized antibody from the surface of a support matrix introduces flexibility, which can reduce steric interferences between antibodies leading to a higher antigen capture efficiency. In this paper we investigated the use of a spacer molecule, poly-ethylene glycol (PEG), between the matrix surface and antibodies for the capture of Bacillus globigii, E. coli O157:H7, and ovalbumin. The antigen capture efficiency was determined using a surface ELISA method. Antibodies against the antigens were covalently immobilized either directly or via PEG to glass surfaces using a one-step EDC reaction. The amount of antibody immobilized was determined before blocking the nonspecific binding sites with bovine serum albumin. Antibodies immobilized via a PEG spacer showed a higher capture efficiency compared to direct immobilization, which was more pronounced with large antigens. Antibodies immobilized on glass supports were stable at 65 degrees C for at least 80 min, and the capture efficiency increased with heating at 65 degrees C for 20 min.     

Analysis of bispecific monoclonal antibody binding to immobilized antigens using an optical biosensor

The interaction between two different monoclonal antibodies (Mabs) and their corresponding bispecific antibodies (Babs) with immobilized antigens was investigated using an optical biosensor (IAsys). The analyzed panel of affinity-purified antibodies included two parental Mabs (one of which was specific to human IgG (hIgG), and another one to horseradish peroxidase (HRP)), as well as Babs derived thereof (anti-hIgG/HRP). Babs resulting from the fusion of parental hybridomas bear two antigen-binding sites toward two different antigens and thus may interact with immobilized antigen through only one antigen-binding site (monovalently). Using an IAsys biosensor this study shows that the bivalent binding of Mabs predominates over the monovalent binding with immobilized HRP, whereas anti-hIgG parental Mabs were bound monovalently to the immobilized hIgG. The observed equilibrium association constant (K _ass) values obtained in our last work [1] by solid-phase radioimmunoassay are consistent with those constants obtained by IAsys. The K _ass of anti-HRP Mabs was about 50 times higher than that of anti-HRP shoulder of Babs. The dissociation rate constant (k _diss) for anti-HRP shoulder of Babs was 21 times higher than k _diss for anti-HRP Mabs. The comparison of the kinetic parameters for bivalent anti-HRP Mabs and Babs derived from anti-Mb/HRP and anti-hIgG/HRP, allowed to calculate that 95% of bound anti-HRP Mabs are bivalently linked with immobilized HRP, whereas only 5% of bound anti-HRP Mabs are monovalently linked. In general, the data obtained indicate that Babs bearing an enzyme-binding site may not be efficiently used instead of traditional antibody–enzyme conjugates in the case of binding of bivalent Mabs.     

Preparation of inert magnetic nano-particles for the directed immobilization of antibodies

Various activated supports (cyanogen bromide, glutaraldehyde, epoxy-chelates, primary amino) were evaluated for the immobilization of IgG anti-horseradish peroxidase. Cyanogen bromide and glutaraldehyde supports greatly reduced the recognition capacity of the antigen, probably due to the incorrect orientation of the antibody on the support. Hetero-functional epoxy-chelate and immobilization by the sugar chain on primary amino groups had little effect on high recognition of the antigen (near to the theoretically expected value). However, the immobilization by the sugar chain resulted in a higher adsorption rate of horseradish peroxidase, possibly due to a favourable orientation on a flexible spacer arm). Antibodies immobilized on aminated surfaces showed two major drawbacks. Firstly, the biological activity of the immobilized antibody sharply decreased over several days when stored at low ionic strength, although this effect could be partially reversed by incubation at high ionic strength. Secondly, a high level of non-specific proteins adsorption on the support surface was observed. Both problems could be successfully resolved by controlling the coating of the support with aldehyde-aspartic-dextran. We propose that the loss of biological activity was related to the ionic adsorption of the immobilized antibody on the support surface, leading to a blocking of the recognition areas. This optimized protocol was applied to the immobilization of IgG anti-horseradish peroxidase from rabbit on magnetic nano-particles. A 10 microg preparation of nano-particles was able to capture more than 75% of the 0.1 microgram of recombinant horseradish peroxidase present in 10 L of crude protein extract (1g/L) from Escherichia coli.     

2种石房蛤毒素完全抗原交联方法的比较及多克隆抗体的制备

[目的]探究石房蛤毒素(STX)完全抗原制备方法和STX多克隆抗体免疫方案。[方法]通过碳二亚胺法(EDC)和高碘酸盐法(periodate reaction)2种交联方法,将小分子石房蛤毒素与牛血清白蛋白(BSA)、鸡卵清蛋白(OVA)和孔血蓝蛋白(KLH)分别进行交联,制备了6种形式STX完全抗原,并对交联物进行琼脂糖凝胶电泳鉴定和紫外吸收峰迁移变化鉴定。分别将EDC法和高碘酸盐法交联的STX-BSA、STX-KLH 4种完全抗原作为免疫原,对Balb/c小鼠进行免疫,获得STX多克隆抗体。通过间接ELISA法,对不同方法制备的多克隆抗体进行分析比较。[结果]在石房蛤毒素完全抗原的制备中,在交联方法的选择上,EDC法较高碘酸盐法更具优势;而在免疫原的选择上,STX-BSA完全抗原效果最好。[结论]本研究探究了2种制备STX完全抗原的方法,为今后多克隆抗体生产以及特异性单克隆抗体筛选提供数据支撑。     

Optimal spacer arm microenvironment for the immobilization of recombinant Protein A on heterofunctional amino-epoxy agarose supports

In this study, recombinant Staphylococcus Protein A (rSPA) was immobilized on three different amino-epoxy agaroses: traditional amino-epoxy, butanediol diglycidyl-amino and glycidyl-amino agarose (coded as AE, BDA and GA agarose, respectively), for obtaining affinity adsorbents to bind human immunoglobulin G (hIgG). The effects of the spacer arm microenvironment of the support on the rSPA immobilization were investigated. Compared with the AE agarose, the GA agarose presents ionized amino groups far from the support. Therefore, the rSPA immobilization efficiency of 92 % is slightly higher than that of 88 % on AE agarose due to the weak steric hindrance. Moreover, the BDA agarose exhibited the lowest immobilization efficiency of 58 %, attributing to the existence of hydrophobic butylidene groups on the BDA agarose. Ethanolamine was used as the blocking agent to obtain three affinity adsorbents. The hIgG-binding capacity from the human plasma was determined to be 18.7, 34.7 and 38.7 mg/mL for rSPA-BDA, rSPA-AE and rSPA-GA, respectively. Furthermore, the maximum hIgG-binding capacity was calculated by the Langmuir model of adsorption isotherm to be 25.1, 44.8 and 52.2 mg/mL for rSPA-BDA, rSPA-AE and rSPA-GA, respectively. Therefore, the GA agarose bears the optimal spacer arm microenvironment for preparing the rSPA adsorbent with high hIgG-binding capacity.     

Covalent immobilization of antibodies on finally inert support surfaces through their surface regions having the highest densities in carboxyl groups

The correct immobilization of antibodies is one of the most critical steps in the preparation of immunosensors and immunochromatography matrices. In addition, the final support has to be chemical and physically inert to avoid the unspecific adsorption of proteins that can reduce the sensitivity of the biosensor or the purification achieved by the chromatography. The solution to both problems is one of the major challenges in the field. Here, we have presented two different novel and simple alternatives to have the unmodified antibody anionically exchanged to a support, further covalently immobilized with more than 90% of the antibodies bonded to the support by the four subunits, retaining a high functionality and giving a final "inert" surface. The first solution was the use of supports having a low superficial density of amino groups activated with glutaraldehyde. Here, the inertness was achieved by the use of a very low density of amino groups, unable to adsorb proteins at 100 mM sodium phosphate, while immobilization proceeds mainly via a first adsorption of the antibody and a further reaction with the glutaraldehyde groups. The second solution implies the design of a novel support (amino-epoxy). This support again produces a first ionic exchange of the antibody on the support and a further reaction with the epoxy groups, but because the epoxy groups can be finally blocked with aspartic groups (annulling the charge), the initial density of amino-epoxy groups can be as high as possible. Both systems permitted the correct and oriented immobilization of IgG. The immobilized antibody showed high-functionality (65-75%) and a final inert support surface. This immobilized antibody (antiperoxidase) was able to capture fully specifically HRP contaminating a protein crude extract from E. coli.     

Optical biosensors for real-time measurement of analytes in blood plasma

The preparation of assemblies consisting of multiple molecular layers of bovine serum albumin (BSA), monoclonal antibodies against horseradish peroxidase (anti-HRP), and monoclonal antibodies against methotrexate (anti-MTT), as well as interaction of the assemblies with human blood plasma were observed using a grating coupler and Young interferometer (YI). The assemblies could be arranged according to decreasing amounts of nonspecific deposits bound irreversibly to them from blood plasma as follows-an adsorbed antibody monolayer saturated with adsorbed BSA, antibody multilayers linked with polycations, antibodies covalently immobilized on a BSA layer densely crosslinked with glutaraldehyde (GA), slightly crosslinked BSA double layer, slightly crosslinked antibody double layers. The occurrence of human serum albumin (HSA), human fibrinogen (Fg), IgG, and IgM in the plasma deposits was studied by binding the respective antibodies. IgG, IgM, and Fg were detected in plasma deposits on the immobilized assemblies while the composition of a plasma deposit on the unmodified sensor surface reflected roughly the plasma composition containing mainly adsorbed HSA and Fg. A crosslinked anti-HRP double layer was immobilized on a waveguiding branch of YI and a similar anti-MTT double layer was immobilized on the other branch. The sensor response to blood plasma was fairly decreased owing to a compensation of the respective optical changes in the two branches, in which a similar non-specific adsorption took place. The addition of HRP or MTT to plasma induced specific responses of the corresponding branches.     

Properties of cellulase immobilized on agarose gel with spacer

Cellulase produced by fungus Trichoderma viride was immobilized on agarose beads (Sepharose 4B) activated by cyanogen bromide and also on activated agarose beads that contained spacer arm (activated CH-Sepharose 4B and Affi-Gel 15). The CMCase activity retained by immobilized cellulase on activated Sepharose containing the spacer tended to be higher than that immobilized without spacer, although the extent of protein immobilization was lower. Also, the higher substrate specificity for cellulase immobilized on beads with spacer was obtained for cellobiose, acid-swollen cellulose, or cellulose powder. The hydrolysis product from their substrates was mainly glucose.     

An approach for the stable immobilization of proteins

An approach is presented for the stable covalent immobilization of proteins with a high retention of biological activity. First, chemical modification studies were used to establish enzyme structural and functional properties relevant to the covalent immobilization of an enzyme to agarose based supports. Heparinase was used as a model enzyme in this set of studies. Amine modifications result in 75-100% activity loss, but the effect is moderated by a reduction in the degree of derivatization. N-hydroxysuccinimide, 1,1,1-trifluoroethanesulfonic acid, and epoxide activated agarose were utilized to determine the effect of amine reactive supports on immobilized enzyme activity retention. Cysteine modifications resulted in 25-50% loss in activity, but free cysteines were inaccessible to either immobilized bromoacetyl or p-chloromercuribenzoyl groups. Amine reactive coupling chemistries were therefore utilized for the covalent immobilization of heparinase. Second, to ensure maximal stability of the immobile protein-support linkage, the identification and subsequent elimination of the principal sources of protein detachment were systematically investigated. By using high-performance liquid chromatography (HPLC), electrophoresis, and radiolabeling techniques, the relative contributions of four potential detachment mechanisms-support degradation, proteolytic degradation, desorption of noncovalently bound protein, and bond solvolysis-were quantified. The mechanisms of lysozyme, bovine serum albumin, and heparinase leakage from N-hydroxysuccinimide or 1,1,1-trifluoroethanesulfonic acid activated agarose were elucidated. By use of stringent postimmobilization support wash procedures, noncovalently bound protein loss. An effective postimmobilization washing procedure is presented for the removal of adsorbed protein and the complete elimination of immobilized protein loss.     

Immobilization of murine lymphocytes by gel entrapment

Summary Murine non-transformed lymphocytes were immobilized by alginate and agarose entrapment. After lipopolysaccharide activation, immunoglobulin production was followed as a criterion of viability of the cells. In alginate beads, diffusion limitations result in cell death. In agarose, the production level of specific antibodies is 40% lower than with suspended cells while immobilization does not alter polyclonal antibody production.     

Solid-phase handling of hydrophobins: immobilized hydrophobins as a new tool to study lipases

Hydrophobins are fungal proteins that self-assemble spontaneously at hydrophilic-hydrophobic interfaces and change the polar nature of the surfaces to which they attach. This attribute can be used to introduce hydrophobic foci on the surface of hydrophilic supports where hydrophobins are attached by covalent binding. In this paper, we report the binding of Pleurotus ostreatus hydrophobins to a hydrophilic matrix (agarose) to construct a support for noncovalent immobilization and activation of lipases from Candida antarctica, Humicola lanuginosa, and Pseudomonas flourescens. Lipase immobilization on agarose-bound hydrophobins proceeded at very low ionic strength and resulted in increased lipase activity and stability. The enzyme could be desorbed from the support using moderate concentrations of Triton X-100, and its enantioselectivity was similar to that of lipases interfacially immobilized on conventional hydrophobic supports. These results suggest that lipase adsorption on hydrophobins follows an "interfacial activation" mechanism; immobilization on hydrophobins offers new possibilities for lipase study and modulation and reveals a new application for fungal hydrophobins.     

BSA和PEG影响固定化辣根过氧化物酶HRP在有机相中活力

ＢＳＡ和ＰＥＧ可以有效地提高固定化辣根过氧化物酶（ＨＲＰ）在有机相中的活力。固定化酶活力的提高与试剂加入的顺序有密切的联系;不同载体对酶的影响不同,Ｇｅｌｉｔｅ,ａｌｕｍｉｎａ,ＸＡＤ－７,Ｋｉｓｅｌｇｅｌ和Ｆｌｏｒｉｓｉｌ为载体,分别以吸附法制备固定化酶。实验表明固定化过程中保护剂和酶的加入顺序与国家化酶活力密切相关,而这些载体的固定化效果又以Ｃｅｌｉｔｅ最佳,Ｆｌｏｒｉｓｉｌ最差。Ｆｌｏｒｉｓ     

A novel bioassay for the monitoring of carcinoembryonic antigen in human biofluid using polymeric interface and immunosensing method

Carcinoembryonic antigen (CEA) is a member of a family of cell surface glycoproteins. Recognition of CEA is needed to monitor the physiological status of the patient for treatment and also it is important to assess the severity of the disease. In this work, we reported a novel sandwich‐type electrochemical immunosensor based on gold nanoparticles functionalized cysteamine‐glutaraldehyde (AuNPs‐CysA‐GA) and it successfully designed to detection of the CEA biomarker in a human plasma sample. The AuNPs‐CysA‐GA provides a large surface area for the effective immobilization of CEA antibody, as well as it ascertains the bioactivity and stability of immobilized CEA antigens. Biotinylated‐anti‐CEA antibody (Ab1) was immobilized on the surface of glassy carbon electrode (GCE) modified AuNPs‐CysA‐GA. Also, secondary antibody (HRP‐Ab2) was costed immobilized to complete the sandwich part of immunosensor. Field emission scanning electron microscope (FE‐SEM and EDS), was employed to monitor the sensor fabrication procedure. The immunosensor was used for the detection of CEA using differential pulse voltammetry (DPVs) technique. The proposed interface led to enhancement of accessible surface area for immobilizing high amount of anti‐CEA antibody, increasing electrical conductivity, boosting stability, and biocompatibility. Finally, the low limit of quantitation (LLOQ) of the proposed immunosensor was obtained as 7 ng/mL with the linear range of 0.001‐5 μg/L. The proposed immunoassay was successfully applied for the monitoring of the CEA in unprocessed human plasma samples. Obtained results paved that the proposed bioassay can be used as a novel bioassay for the clinical diagnosis of cancer based on CEA monitoring.     

Assay sensitivity and differentiation of monoclonal antibody specificity in ELISA with different coating buffers

Buffers of different pH and ionic strength were employed as coating buffers for antigen adsorption to microtitre plates. Their efficiency for coating plates with rinderpest virus (RPV) and foot-and-mouth disease virus (FMDV) antigens was studied by ELISA with polyclonal and monoclonal antibody preparations. While the adsorption and detection of RPV antigen with polyclonal antiserum was highly dependent on the ionic strength and pH of coating buffer, adsorption of antigenically active FMDV antigen was relatively unaffected by the buffering conditions. Both antigens were adsorbed optimally in 0.01 M phosphate buffer, pH 8.0. When monoclonal antibodies were used to detect antigen, there was a greater degree of dependence on the coating buffer than that found with polyclonal antisera. Moreover, when they were used to detect antigen adsorbed under several buffering conditions, monoclonal antibodies showed a variety of preferred buffers. The usefulness of this differential reactivity in distinguishing epitope specificity is demonstrated.     

Stabilization of a raw starch digesting amylase from Aspergillus carbonarius via immobilization on activated and non-activated agarose gel

Applications of raw starch digesting amylases (RSDAs) are limited due to instability, product inhibition of enzyme and contamination. RSDA from Aspergillus carbonarius was stabilized through immobilization on agarose gel by adsorption, spontaneous crosslinking and conjugation using glycidol, glutaraldehyde or polyglutaraldehyde. Effects of immobilization on kinetics, catalytic, storage and operational stability of immobilized enzyme were evaluated. Polyglutaraldehyde activated agarose RSDA (PGAg-RSDA) gave the highest immobilization yield (100%) with expressed activity of 86.7% while that of glycidol activated RSDA (GlyAg-RSDA) was 80.4%. A shift in pH from optimum of 5 for the soluble enzyme to 6 for RSDA adsorbed on agarose followed by crosslinking with glutaraldehyde (AgRSDA-CROSS) and simultaneous adsorption and crosslinking (AgRSDA-RET), and pH 7 for PGAg-RSDA was seen. PGAg-RSDA and AgRSDA-CROSS were most pH stable and retained over 82% of their activities between pH 3.5 and 9 compared to 59% for the soluble enzyme. Thermoinactivation studies showed that immobilized RSDAs with the exception of GAg-RSDA retained over 90% of their activities at 60°C for 120 min while soluble enzyme retained only 76% activity under the same condition. AgRSDA-CROSS, PGAg-RSDA, Gly-RSDA and GAg-RSDA retained approximately 100% of their activities after 30 days storage at 4°C. GlyAg-RSDA retained 99.6%, PGAg-RSDA 94%, AgRSDA-CROSS 90%, GAg-RSDA 86.5% and Ag-RSDA-RET 80% activity after 10 batch reactions. Immobilization stabilized RSDA and permits processing at higher temperatures to reduce contamination.     

Essential role of the concentration of immobilized ligands in affinity chromatography:: Purification of guanidinobenzoatase on an ionized ligand

Guanidinobenzoatase, a plasma protein with possible application as a ‘tumor marker’, has been fully purified by one-step affinity chromatography. The affinity matrix was prepared by ‘controlled’ immobilization of an enzyme inhibitor (agmatine) onto commercial agarose gels containing carboxyl moieties activated as N-hydroxysuccinimide esters. In this way, agmatine becomes immobilized through an amido bond and preserves an ionized guanidino moiety. Different matrices with different concentration of ligands were prepared in order to evaluate their properties as affinity supports. Interestingly, matrices with a very low concentration of immobilized ligands (2 μmol/ml, corresponding to the modification of only 5% of active groups in the commercial resins) exhibited a low capacity for unspecific adsorption of proteins (as anion-exchange resins) and displayed also a high capacity for specific adsorption of our target protein. On the other hand, when affinity matrices possessed a moderate concentration of agmatine (10 μmol/ml of gel or higher), two undesirable phenomena were observed: (a) the matrix behaves as a very good anionic exchange support able to non-specifically adsorb most of plasma proteins and (b) the specific adsorption of our target protein becomes much lower. The latter phenomenon could be due to steric hindrances promoted by the interaction between each individual immobilized ligand and the corresponding binding pocket in the target protein. These hindrances could also be promoted by the presence of a fairly dense layer of immobilized ligands covering the support surface, thus preventing interactions between immobilized ligands and partially buried protein-binding pockets. In this way, a successful affinity purification (23.5% yield, ×220 purification factor, a unique electrophoretic band) could be achieved by combination of three approaches: (i) the use of affinity matrices possessing a very low density of immobilized ligands, (ii) performing affinity adsorption at high ionic strength and (iii) performing specific desorption with substrates or substrate analogues.     

Polymer nanoparticles covered with phosphorylcholine groups and immobilized with antibody for high-affinity separation of proteins

Novel polymer nanoparticles were prepared for the selective capture of a specific protein from a mixture with high effectiveness. The nanoparticle surface was covered with hydrophilic phosphorylcholine groups and active ester groups for easy immobilization of antibodies. Phospholipid polymers (PMBN) composed of 2-methacryloyloxyethyl phosphorylcholine, n-butyl methacrylate, and p-nitrophenyloxycarbonyl polyethyleneglycol methacrylate, were synthesized for the surface modification of poly( l-lactic acid) nanoparticles. Surface analysis of the nanoparticles using laser-Doppler electrophoresis and X-ray photoelectron spectroscopy revealed that the surface of nanoparticles was covered with PMBN. Protein adsorption was evaluated with regard to the nonspecific adsorption on the nanoparticles that was effectively suppressed by the phosphorylcholine groups. The immobilization of antibodies on nanoparticles was carried out under physiological conditions to ensure specific binding of antigens. The antibody immobilized on the nanoparticles exhibited high activity and strong affinity for the antigen similar to that exhibited by an antibody in a solution. The selective binding of a specific protein as an antigen from a protein mixture was relatively high compared to that observed with conventional antibody-immobilized polymer nanoparticles. In conclusion, nanoparticles having both phosphorylcholine and active ester groups for antibody immobilization have strong potential for use in highly selective separation based on the biological affinities between biomolecules.     

Modulation of the distribution of small proteins within porous matrixes by smart-control of the immobilization rate

The distribution of enzymes attached to porous solid supports is a major concern in multienzymatic bioreactors. Herein, as proof of the concept that protein localization on porous surfaces can be controlled by tuning the protein immobilization rate. We study the distribution of two poly-histidine-tagged fluorescent proteins (His-GFP and His-mCherryFP) immobilized on different 4% crosslinked agarose-type carriers by confocal laser scanning microscopy. In this context, immobilization rate is easily modulated by controlling the (i) nature of physico-chemical interaction between protein and surface (reactive groups on surface), (ii) by controlling the reactive group density and (iii) by adding competitors to the immobilization process. His-GFP is 350-fold more rapid immobilized on agarose surfaces activated with either glyoxyl groups or chelates than the same matrix activated with primary amine groups instead. A similar effect is seen with agarose matrixes activated with lower glyoxyl densities that immobilize His-GFP roughly 350-fold slower than the corresponding highly activated matrix. When His-GFP is immobilized on agarose activated with chelates groups in presence of imidazol which competes with the protein for the reactive groups on the support, the immobilization rate is again 400-fold slower than when the same protein was immobilized on the same support but with no imidazol during the immobilization process. In all cases, it was observed that rapid immobilizations (quantitative immobilization in less than 10 min) located 100% of the loaded protein at the crown of the carrier beads, meaning that only the 10% of the bead radius was colonized by the protein. On the contrary, when immobilization is much slower, a homogeneous distribution is obtained, resulting in beads whose whole radius is occupied by the protein. Therefore, we set that the more rapid immobilization, the more heterogeneous distribution. All the knowledge gained in protein distribution by immobilization rate alteration of a single protein is applied to the co-immobilization of the two fluorescent proteins in order to develop four different co-immobilization patterns with an enormous applied potential to other multi-protein systems.