Affinity cross-flow filtration: purification of IgG with a novel protein a affinity matrix prepared from two-dimensional protein crystals

In this article, we describe the use of 1- to 2-mum sized affinity microparticles for the isolation and purification of IgG from artificial IgG-human serum albumin mixtures and clarified hybridoma cell culture supernatants by affinity cross-flow filtration. Affinity microparticles were prepared from cell wall fragments of Clostridium thermohydrosulfuricum L111-69, in which the peptidoglycan-containing layer was completely covered with a hexagonally ordered S-layer lattice. After crosslinking the S-layer protein with glutaraldehyde, carboxyl groups from acidic amino acids were activated with carbodiimide and used for immobilization of Protein. A. Quantitative determination confirmed that Protein A molecules formed a monomolecular layer on the outermost surface of the S-layer lattice. Affinity microparticles were found to withstand high centrifugal and shear forces and revealed no Protein A leakage or S-layer protein release under cross-flow conditions between pH 2 to 12. The IgG-binding capacity of affinity microparticles was investigated under crossflow conditions and compared with that obtained in batch adsorption processes. (c) 1994 John Wiley & Sons, Inc.     

Simultaneous uptake and utilisation of glucose and xylose by Clostridium thermohydrosulfuricum

Abstract Growth studies of Clostridium thermohydrosulfuricum Rt8.B1 demonstrated that glucose and xylose were used simultaneously when supplied together at nonlimiting concentrations in pH-controlled batch culture. Under conditions of hyperbolic growth, both catabolite repression and inducer exclusion were absent. Glucose did not repress xylose metabolism (i.e. xylose permease and xylose isomerase genes were expressed in the presence of glucose and were not subject to catabolite inhibition when glucose was added to cultures growing on high concentrations of xylose). The kinetics of glucose and xylose utilisation indicated that separate systems were present for the uptake of these substrates when supplied together. Glucose utilisation was biphasic, indicating high- and low-affinity systems for glucose uptake. Xylose utilisation was directly proportional to the xylose concentration, suggesting a facilitated diffusion mechanism was operative for uptake.     

A synthetic medium for continuous culture of the S-layer carrying Bacillus stearothermophilus PV 72 and studies on the influence of growth conditions on cell wall properties

Bacterial cell surface layers (S-layers) which show a crystalline structure, defined pores, and a regular arrangement of functioal groups can be used for production of isoporous ultrafiltration membranes and as a matrix for immobilization of macromolecules. S-layer-carrying cell wall fragments from thermophilic Bacillaceae possess an extremely thin peptidoglycan-containing layer with pores larger than those in the S-layer lattice. Thus, they can directly be used for biotechnological applications, when an S-layer protein pool is stored in the rigid cell wall layer which is released during cell wall preparation, forming an inner S-layer. In the present study, a synthetic medium for Bacillus stearothermophilus PV 72 was developed by applying the pulse and shift technique with the aim to produce cell wall fragments with before-mentioned properties by varying the growth conditions in condtinuous culture. The organism was grown at 57 degrees C in a bioreactor with 1 L working volume equipped with exhaust gas analysis and connected to a PC-based process control system. Biomass concentration was 2.2 g/L out of 8 g/L glucose at a dilution rate of 0.3 h(-1), giving a biomass productivity of 0.66 g/L h. Although the organism was grown under different conditions, no change in peptidoglycan composition, extent of peptidoglycan crosslinking, and content of secondary cell wall polymers was observed. The amount of S-layer protein pool stored in the rigid cell wall layer and the autolytic activity depended mainly on the specific growth rate. Cell wall fragments with properties required for ultrafiltration membrane production could be produced by parameter settings in continuous culture. (c) 1995 John Wiley & Sons, Inc.     

Production of novel pullulanases at high concentrations by two newly isolated thermophilic clostridia

Two thermophilic bacteria, which are capable of growing on starch at 60-70 degrees C under anaerobic conditions, were isolated from a sugar refinery in Uelzen and from Solar lake in Israel. On the basis of their physiological characteristics they were identified as Clostridium thermohydrosulfuricum Uel 1 and C. thermohydrosulfuricum Sol 1, respectively. The product pattern of glucose polymer hydrolysis showed that both strains secreted enzymes that possess amylolytic and pullulytic activities. The major product formed was maltose. In addition, alpha-glucosidase activity could be detected in the supernatants of Uel 1 strain. Compared to most anaerobes investigated these isolates secreted extremely high concentrations of pullulanases in batch culture. Up to 85% of the total enzyme synthesized was detected in the culture fluid. Unlike the pullulanases of type I, which can only attack the alpha-1,6-glycosidic linkages, the pullulanases of both clostridial strains were also capable of hydrolyzing alpha-1,4-linkages. The enzyme system of both bacteria was found to be highly thermoactive; optimal activity was detected at pH 5.0 and 85 degrees C. Even at 95 degrees C and without the addition of metal ions still 15% to 25% of enzymatic activity was detectable.     

Protein a resin lifetime study: Evaluation of protein a resin performance with a model-based approach in continuous capture

A modified shrinking core model (MSCM) has been used to describe the mechanism for the degradation of Protein A resin particles taking place under continuous chromatographic operation. The model is based on the hypothetical shrinkage of the boundary layer of the resin particles, which house the active Protein A ligands within their pores. The caustic during the sanitization phase of chromatography has been determined to cause the Protein A ligand degradation. Protein A resins provided by manufacturers possess unique caustic stability, which has been used in MSCM to appraise the ligand degradation. The kinetic model utilized semiempirical parameters including diffusion constant, rate constant, stoichiometric factor, and reaction order. The parameters were estimated from column breakthrough experiments to simulate continuous Protein A chromatography for three distinct resins. The reaction order has been identified as the key parameter for predicting the degradation kinetics. The recorded reaction orders vary for three different resins with the resin B showing the highest reaction order of 4 and lowest being 1.65 for the resin C. The model can predict the effects of caustic on resin performance and displayed that minimal degradation of the resins A and B occurred, when exposed to 0.1?N and 0.2N NaOH, retaining up to 96% binding capacity after 240?cycles. The adsorption study conducted for the resin B demonstrated the dynamic physical and chemical changes transpiring through the life cycle of the resin, further supported the degradation model. The performance data demonstrate that the resin B exhibits the desirable performance, with higher reaction order indicating slower resin degradation, higher binding capacities, and increased sustenance of this binding capacity for extended duration. The degradation model can be extended to build effective cleaning strategies for continuous downstream processing.     

Improvement of antibody immobilization using hyperbranched polymer and protein A

For the construction of a well-defined antibody surface, protein A was used as a binding material to immobilize antibodies onto gold-derivatized transducers. The traditional method tends to assemble protein A directly onto the gold-derivatized transducers. In this paper, we tried to indirectly bind protein A onto sensors through hyperbranched polymer (HBP) which was synthesized from p-phenylenediamine and trimesic acid. The three-dimensional structure of HBP and the characteristics including orientation control and biocompatibility of protein A led to highly efficient immunoreactions and enhanced detection system performance. With this strategy, cysteamine monolayer was first assembled onto Au electrodes associated with the piezoelectric quartz crystal; secondly, the cysteamine-modified gold electrode was further modified by the activated HBP; thirdly, protein A was immobilized onto the HBP film; and finally, antibodies were immobilized onto the surface of protein A film for detecting the corresponding antigen. The quartz crystal microbalance immunosensor thus fabricated was applied to detect hepatitis B surface antigen in solutions that ranged from 0.71 to 300 μg mL⁻¹. The detection limit was estimated to be 0.53 μg mL⁻¹. The immunosensor holds good selectivity, sensitivity, and repeatability.     

Identification and Purification of an External Antigenic Glycoprotein (Immobilization Antigen) From Pseudomicrothorax Dubius

SYNOPSIS. A large, external glycoprotein with antigenic properties isolated from the ciliate Pseudomicrothorax dubius was found to have a molecular weight of ∼ 250,000 daltons. Analysis of the extracts by isoelectric focusing in combination with immunodiffusion and gradient polyacrylamide gel electrophoresis revealed that the principal antigen was a large glycoprotein. the glycoprotein was purified partially by Sephadex ultrafiltration. and almost completely by affinity chromatography on a concanavalin A-Sepharose column.     

Bionanocapsule-based enzyme-antibody conjugates for enzyme-linked immunosorbent assay

Macromolecules that can assemble a large number of enzyme and antibody molecules have been used frequently for improvement of sensitivities in enzyme-linked immunosorbent assays (ELISAs). We generated bionanocapsules (BNCs) of approximately 30 nm displaying immunoglobulin G (IgG) Fc-binding ZZ domains derived from Staphylococcus aureus protein A (designated as ZZ-BNC). In the conventional ELISA using primary antibody and horseradish peroxidase-labeled secondary antibody for detecting antigen on the solid phase, ZZ-BNCs in the aqueous phase gave an approximately 10-fold higher signal. In Western blot analysis, the mixture of ZZ-BNCs with secondary antibody gave an approximately 50-fold higher signal than that without ZZ-BNCs. These results suggest that a large number of secondary antibody molecules are immobilized on the surface of ZZ-BNCs and attached to antigen, leading to the significant enhancement of sensitivity. In combination with the avidin-biotin complex system, biotinylated ZZ-BNCs showed more significant signal enhancement in ELISA and Western blot analysis. Thus, ZZ-BNC is expected to increase the performance of various conventional immunoassays.     

A study of the interactions between an IgG-binding domain based on the B domain of staphylococcal protein a and rabbit IgG

The nonantigenic interaction between a recombinant immunoglobulin G (IgG)-binding protein based on the B domain of Protein A fromStaphylococcus aureus (termed SpA¹) and the Fc fragment of rabbit IgG has been investigated. The contribution to binding of four putative hydrogen bond contacts between SpA¹ and IgG-Fc were examined by the individual substitution of the residues in SpA¹ involved in these interactions by others unable to form hydrogen bonds. It was found that the most important of the hydrogen bonds involved Tyr 18 which, when replaced by Phe, resulted in a twofold decrease in IgG-binding affinity. The residues of SpA¹ proposed to make close, mainly hydrophobic, contacts with Fc were replaced by residues with potential electrostatic charge to establish the importance of the hydrophobic interaction in the complex. The IgG-binding affinities of the mutant proteins were compared to the wild-type protein by a competitive enzyme-linked immunosorbant assay. The replacement of individual hydrophobic residues by His generated a number of novel IgG-binding proteins with reduced binding affinity at pH 5.0 but which maintained strong binding affinities at pH 8.0. The elution profile of human IgG₁-Fc (Fc fragment of human IgG₁) from a column made from an immobilized two-domain mutant protein shows that the complex dissociates at a higher pH relative to that of the non-mutated protein thus offering favorable elution characteristics.     

Immobilization of immunoglobulin-G-binding domain of Protein A on a gold surface modified with biotin ligase

Protein A from Staphylococcus aureus specifically binds to the Fc region of immunoglobulin G (IgG) and is widely used as a scaffold for the immobilization of IgG antibodies on solid supports. It is known that the oriented immobilization of Protein A on solid supports enhances its antibody-binding capability in comparison with immobilization in a random manner. In the current work, we developed a novel method for the oriented immobilization of the IgG-binding domain of Protein A based on the biotinylation reaction from archaeon Sulfolobus tokodaii. Biotinylation from S. tokodaii has a unique property in that the enzyme, biotin protein ligase (BPL), forms a stable complex with its biotinylated substrate protein, biotin carboxyl carrier protein (BCCP). Here, BCCP was fused to the IgG-binding domain of Protein A, and the resulting fusion protein was immobilized on the BPL-modified gold surface of the sensor chip for quartz crystal microbalance through complexation between BCCP and BPL. The layer of the IgG-binding domain prepared in this way successfully captured the antibody, and the captured antibody retained high antigen-binding capability.     

S-layers as a tool kit for nanobiotechnological applications

Crystalline bacterial cell surface layers (S-layers) have been identified in a great number of different species of bacteria and represent an almost universal feature of archaea. Isolated native S-layer proteins and S-layer fusion proteins incorporating functional sequences self-assemble into monomolecular crystalline arrays in suspension, on a great variety of solid substrates and on various lipid structures including planar membranes and liposomes. S-layers have proven to be particularly suited as building blocks and patterning elements in a biomolecular construction kit involving all major classes of biological molecules (proteins, lipids, glycans, nucleic acids and combinations of them) enabling innovative approaches for the controlled 'bottom-up' assembly of functional supramolecular structures and devices. Here, we review the basic principles of S-layer proteins and the application potential of S-layers in nanobiotechnology and biomimetics including life and nonlife sciences.     

Large scale modification of biomolecules using immobilized sortase A from Staphylococcus aureus

Recently, sortase A (SrtA) from Staphyloccus aureus moved into the focus of bioscience because of its ability to incorporate site specific modifications into proteins. The enzyme was mostly used to modify target proteins in an analytical scale, to study biomolecules in their cellular context. In this study, we show the applicability of SrtA mediated ligation for site specific modification of proteins in a large scale. Therefore, the reaction was first optimized using peptides and subsequently new reaction conditions were applied for the large scale biotinylation of interleukin-8. Furthermore, we established C-terminal immobilization of the SrtA on a PEG based resin and could demonstrate maintaining enzymatic activity. Immobilized SrtA significantly facilitates previous ligation protocols as the enzyme can be easily recycled. Also, the removal of excess reaction solution and the whole washing process is significantly accelerated, as centrifugation or filtration techniques can be applied instead of time-consuming chromatography steps.     

Adaptation of Clostridium difficile toxin A for use as a protein translocation system

A cellular delivery system is a useful biotechnology tool, with many possible applications. Two derivatives of Clostridium difficile toxin A (TcdA) have been constructed (GFP-TcdA and Luc-TcdA), by fusing reporter genes to functional domains of TcdA, and evaluated for their ability to translocate their cargo into mammalian cells. The cysteine protease and receptor binding domains of TcdA have been examined and found to be functional when expressed in the chimeric construct. Whereas GFP failed to internalize in the context of the TcdA fusion, significant cellular luciferase activity was detected in vero cell lysates after treatment with Luc-TcdA. Treatment with bafilomycin A1, which inhibits endosomal acidification, traps the luciferase activity within endosomes. To further understand these results, clarified lysates were subjected to molecular weight sieving, demonstrating that active luciferase was released from Luc-TcdA after translocation and internal processing.     

How reliable is amino acid sequence homology in predicting similarity of structure and function of c-myc and Ad12 E1A oncogenic proteins?

Summary Adenovirus E1A and c-myc genes are known to be capable of transforming primary rat cells when they occur in combination with either polyoma middle-T or T24 Harvey-ras 1 genes. There was a low level of amino acid sequence homology between the nuclear adenovirus-12 (Ad12) E1A protein product (289 amino acids) and the c-myc protein based on optimal alignment and percentage identity. In contrast to others [Ralston R, Bishop JM (1983) Nature 306:803–806], we concluded that this low level of amino acid sequence homology was not significant, since rabies glycoprotein (RGP), which has no transforming function and localizes to the cell surface, had a similar low level of amino acid sequence homology to the c-myc protein. Furthermore, dot-matrix analysis, when used to test the overall level of amino acid sequence homology, showed no significant homology between c-myc and Ad12 E1A, E1B, or RGP. Thus, low levels of amino acid sequence homology between two proteins may not be sufficient to predict structural and functional similarities between them reliably, even if the two proteins appear to share a common function.