Improvement of production,assay and purification of streptavidin

Summary The production of streptavidin byStreptomyces avidinii in several different media was examined at 24, 48 and 72 hours. Flask studies indicated that fermentation media containing either complex or multiple carbon sources resulted in higher yields of streptavidin than media with a single carbon source. Streptavidin could be detected in crude fermentation broths by use of a tritiated biotin binding assay. This assay appears to give useful estimates of streptavidin production. Depending upon the medium employed, streptavidin yields ranged from 0.5 mg/l to 53 mg/l. Production was successfully scaled up to ten liter fermentors. Streptavidin was purified in a one step process from centrifuged, concentrated fermentation broths by binding the protein to an iminobiotin column at pH 11 followed by elution at pH 4.0. Recovery percentages varied depending upon the solubility of the fermentation media ingredients.     

Interstrand loops CD and EF act as pH-dependent gates to regulate fatty acid ligand binding in tear lipocalin

Tear lipocalin (TL), a major component of human tears, shows pH-dependent endogenous ligand binding. The structural and conformational changes associated with ligand release in the pH range of 7.5-3.0 are monitored by circular dichroism spectroscopy and site-directed tryptophan fluorescence. In the transition from pH 7.5 to pH 5.5, the ligand affinity for 16-(9-anthroyloxy)palmitic acid (16AP) and 8-anilino-1-naphthalenesulfonic acid is reduced. At pH 4.0 these ligands no longer bind within the TL calyx. From pH 7.3 to pH 3.0, the residues on loops CD and EF, which overhang the calyx entrance, show reduced accessibility to acrylamide. In addition resonance energy transfer is enhanced between residues on the two loops; the distance between the loops narrows. These findings suggest that apposition of the loops at low pH excludes the ligand from the intracavitary binding site. The conformational changes observed in transition from pH 7.3 to pH 3.0 for loops CD and EF are quite different. The CD loop shows less population reshuffling than the EF loop with an acidic environment, probably because backbone motion is restrained by the adjacent disulfide bond. The Trp fluorescence wavelength maximum (lambda(max)) reflects internal electrostatic interactions for positions on loops CD and EF. The titration curves of lambda(max) for mutants on the EF loop fit the Hendersen-Hasselbalch equation for two apparent pK(a) values, while the CD loop positions fit satisfactorily with one pK(a) value. Midpoints of transition for the binding affinity of TL tryptophan mutants to 16AP occur at pH 5.5-6.1. Replacement of each amino acid on either loop by single tryptophan mutation does not disrupt the pH-dependent binding affinity to 16AP. Taken together the data suggest that pH-driven ligand release involves ionization changes in several titratable residues associated with CD and EF loop apposition and occlusion of the calyx.     

Studies on the mechanism of the malate dehydrogenase reaction.

The stereospecificity of the chicken heart mitochondrial malate dehydrogenase as well as the ability of this enzyme to form various abortive complexes has been further investigated. The enzyme was found to be specific for the A-hydrogen of NADH. Complex formation of the enzyme with oxalacetate and oxidized coenzymes is pH-dependent and is promoted at alkaline pH values. The enol form of oxalacetate appears to be the species that participates in the formation of the complexes. The binding of L-malate, D-malate, or hydroxymalonate to the enzyme. NADH complex is also pH-dependent, and involves a group on the enzyme with a pK of 7.5. The binding of L-malate is promoted at alkaline pH values, whereas the binding of D-malate and hydroxymalonate is favored at acidic pH values. These results indicate that L-malate and enol-oxalacetate preferentially or exclusively bind to the nonprotonated form of the enzyme, whereas keto-oxalactate, hydroxymalonate, and D-malate only bind to the protonated form of the enzyme. Based on this conclusion, a detailed chemical mechanism for the malate dehydrogenase reaction has been postulated and a schematic illustration of the transition state of the enzyme is presented.     

Plug-and-Play Pairing via Defined Divalent Streptavidins

Streptavidin is one of the most important hubs for molecular biology, either multimerizing biomolecules, bridging one molecule to another, or anchoring to a biotinylated surface/nanoparticle. Streptavidin has the advantage of rapid ultra-stable binding to biotin. However, the ability of streptavidin to bind four biotinylated molecules in a heterogeneous manner is often limiting. Here, we present an efficient approach to isolate streptavidin tetramers with two biotin-binding sites in a precise arrangement, cis or trans. We genetically modified specific subunits with negatively charged tags, refolded a mixture of monomers, and used ion-exchange chromatography to resolve tetramers according to the number and orientation of tags. We solved the crystal structures of cis-divalent streptavidin to 1.4 Å resolution and trans-divalent streptavidin to 1.6 Å resolution, validating the isolation strategy and explaining the behavior of the Dead streptavidin variant. cis- and trans-divalent streptavidins retained tetravalent streptavidin's high thermostability and low off-rate. These defined divalent streptavidins enabled us to uncover how streptavidin binding depends on the nature of the biotin ligand. Biotinylated DNA showed strong negative cooperativity of binding to cis-divalent but not trans-divalent streptavidin. A small biotinylated protein bound readily to cis and trans binding sites. We also solved the structure of trans-divalent streptavidin bound to biotin-4-fluorescein, showing how one ligand obstructs binding to an adjacent biotin-binding site. Using a hexaglutamate tag proved a more powerful way to isolate monovalent streptavidin, for ultra-stable labeling without undesired clustering. These forms of streptavidin allow this key hub to be used with a new level of precision, for homogeneous molecular assembly.     

Two-dimensional crystals of streptavidin on biotinylated lipid layers and their interactions with biotinylated macromolecules.

Streptavidin forms two-dimensional crystals when specifically bound to layers of biotinylated lipids at the air/water interface. The three-dimensional structure of streptavidin determined from the crystals by electron crystallography corresponds well with the structure determined by x-ray crystallography. Comparison of the electron and x-ray crystallographic structures reveals the occurrence of free biotin-binding sites on the surface of the two-dimensional crystals facing the aqueous solution. The free biotin-binding sites could be specifically labeled with biotinylated ferritin. The streptavidin/biotinylated lipid system may provide a general approach for the formation of two-dimensional crystals of biotinylated macromolecules.     

链霉亲和素及其亲和系统的蛋白质进化

链霉亲和素/生物素（Streptavidin/Biotin）体系作为目前已知的最高亲和力作用体系,已在生物学研究中获得广泛应用。本文针对Streptavidin/Biotin和Strep-Tactin/Strep-tag两个相关系统的演化,分别从链霉亲和素蛋白的结构改造、亲和肽标签优化等方面进行了较为详细的归纳。通过对链霉亲和素蛋白各种突变体的优缺点的比较,有助于实际应用中选择合适的Streptavidin突变体。本文通过对链霉亲和素蛋白质进化的综述,可帮助更准确地理解市场上各种链霉亲和素蛋白的功能和用途,并为深入研究链霉亲和素蛋白的进化提供参考。     

Catalytic function and local proton structure at the type 2 copper of nitrite reductase: the correlation of enzymatic pH dependence,conserved residues,and proton hyperfine structure

Electron nuclear double resonance (ENDOR) of protons at Type 2 and Type 1 cupric active sites correlates with the enzymatic pH dependence, the mutation of nearby conserved, nonligating residues, and electron transfer in heterologously expressed Rhodobacter sphaeroides nitrite reductase. Wild-type enzyme showed a pH 6 activity maximum but no kinetic deuterium isotope effect, suggesting protons are not transferred in the rate-limiting step of nitrite reduction. However, protonatable Asp129 and His287, both located near the Type 2 center, modulated enzyme activity. ENDOR of the wild-type Type 2 center at pH 6.0 revealed an exchangeable proton with large hyperfine coupling. Dipolar distance estimates indicated that this proton was 2.50-2.75 or 2.25-2.45 A from Type 2 copper in the presence or absence of nitrite, respectively. This proton may provide a properly oriented hydrogen bond to enhance water formation upon nitrite reduction. This proton was eliminated at pH 5.0 and showed a diminished coupling at pH 7.5. Mutations of Asp129 and His287 reduced enzyme activity and altered the exchangeable proton hyperfine spectra. Mutation of Asp129 prevented a pH-dependent change at the Type 1 Cys167 ligand as observed by Cys C(beta) proton ENDOR, implying there is a Type 2 and pH-dependent alteration of the Type 1 center. Mutation of the Type 1 center ligand Met182 to Thr and mutation of Asp129 increased the activation energy for nitrite reduction. Involvement of both the Type 1 center and Asp129 in modulating activation energy shows that electron transfer from the Type 1 center to a nitrite-ligated Type 2 center is rate-limiting for nitrite reduction. Mutation of Ile289 to Ala and Val caused minor perturbation to enzyme activity, but as detected by ENDOR, allowed formate binding. Thus, bulky Ile289 may exclude non-nitrite ligands from the Type 2 active site.     

Structural insights into the mechanism of pH-dependent ligand binding and release by the cation-dependent mannose 6-phosphate receptor

The cation-dependent mannose 6-phosphate receptor (CD-MPR) is a key component of the lysosomal enzyme targeting system that binds newly synthesized mannose 6-phosphate (Man-6-P)-containing acid hydrolases and transports them to endosomal compartments. The interaction between the MPRs and its ligands is pH-dependent; the homodimeric CD-MPR binds lysosomal enzymes optimally in the pH environment of the trans Golgi network (pH approximately 6.5) and releases its cargo in acidic endosomal compartments (相似文献   

Biotinylated antibodies bound to streptavidin beads: a versatile solid matrix for immunoassays.

Streptavidin was covalently bound to commercially available polyacrylamide beads (3-10 microns diameter) by peptide bond formation between the carboxyl groups on the solid matrix and the amino groups of the soluble protein. Biotinylated antibody or lectin was linked to the polyacrylamide beads via the streptavidin molecules. Immunoassays for human IgA1, IgA2, IgE, and vitronectin were developed utilizing the antibody or lectin as a capture ligand. The protein being assayed was quantitated colorimetrically at 492 nm via horseradish peroxidase-conjugated antibodies.     

Ligand binding properties of hemoglobin 3 of the trout, Salmo gairdneri. The occurrence of an acid Bohr effect in the absence of heme-heme interaction.

The four components of hemoglobin from the rainbow trout (Salmo gairdneri) have been isolated. The oxygen affinities of the first two components eluted from the DEAE-cellulose column have much smaller pH dependencies than the last two components. These components have very low O2 affinities at low pH. The effect of pH on the equilibrium and kinetics of ligand binding to the third fraction, the pH-dependent component present in greatest amounts, has been studied. Measurements of ligand binding equilibria demonstrate the presence of both an alkaline and an acid Bohr effect. In the region of the alkaline Bohr effect the value of n in the Hill equation is a function of ligand affinity. For CO binding n decreases as the pH is decreased until at pH 6, the minimum ligand affinity is reached. At this pH there is also a complete loss of cooperative ligand binding. Decreasing the pH further results in an increase of ligand affinity, but this acid Bohr effect is not associated with a reappearance of cooperativity. This suggests that Fraction 3 of S. gairdneri is frozen in the low affinity, deoxygenated conformation at low pH and that the quaternary structure does not change even when fully liganded. However, the properties of the low affinity conformation of this hemoglobin are pH-dependent.     

Purification, pH-dependent conformational change, aggregation, and secretory granule membrane binding property of secretogranin II (chromogranin C).

Secretogranin II (SgII) is one of the three major proteins, the other two being chromogranins A (CGA) and B (CGB), of secretory granules of neuroendocrine cells. The Ca(2+) storage proteins CGA and CGB not only are coupled to the IP(3) receptor (IP(3)R)/Ca(2+) channels that exist on the secretory granule membrane but also are known to play key roles in secretory granule biogenesis. Unlike the better studied CGA and CGB, secretogranin II has never been completely purified in the native state and studied. We have therefore purified SgII in native form from bovine adrenal medulla and subjected it to biochemical characterization. Secretogranin II consisted of largely beta-sheet and random coil structures with a low level of alpha-helicity. Like CGA and CGB, it also underwent pH-dependent conformational changes, showing 9.5% alpha-helicity at pH 7.5 and 17.0% alpha-helicity at pH 5.5. Secretogranin II also underwent acidic pH- and Ca(2+)-dependent aggregation, and it was approximately 8-fold more sensitive than CGA to Ca(2+) in its pH-dependent aggregation but was 8-fold less sensitive than CGB. Further, similar to CGA and CGB that had interacted with the secretory granule membrane at the intragranular pH 5.5, SgII also interacted with the secretory granule membrane at pH 5.5 and dissociated from it at near-physiological pH 7.5, implying similar roles of SgII in the cell as those of CGA and CGB. Secretogranin II hence appeared to actively participate in secretory granule biogenesis as has been proposed for CGA and CGB.     

pH dependence of copper geometry, reduction potential, and nitrite affinity in nitrite reductase

Many properties of copper-containing nitrite reductase are pH-dependent, such as gene expression, enzyme activity, and substrate affinity. Here we use x-ray diffraction to investigate the structural basis for the pH dependence of activity and nitrite affinity by examining the type 2 copper site and its immediate surroundings in nitrite reductase from Rhodobacter sphaeroides 2.4.3. At active pH the geometry of the substrate-free oxidized type 2 copper site shows a near perfect tetrahedral geometry as defined by the positions of its ligands. At higher pH values the most favorable copper site geometry is altered toward a more distorted tetrahedral geometry whereby the solvent ligand adopts a position opposite to that of the His-131 ligand. This pH-dependent variation in type 2 copper site geometry is discussed in light of recent computational results. When co-crystallized with substrate, nitrite is seen to bind in a bidentate fashion with its two oxygen atoms ligating the type 2 copper, overlapping with the positions occupied by the solvent ligand in the high and low pH structures. Fourier transformation infrared spectroscopy is used to assign the pH dependence of the binding of nitrite to the active site, and EPR spectroscopy is used to characterize the pH dependence of the reduction potential of the type 2 copper site. Taken together, these spectroscopic and structural observations help to explain the pH dependence of nitrite reductase, highlighting the subtle relationship between copper site geometry, nitrite affinity, and enzyme activity.     

pH-Dependent structural changes at Ca(2+)-binding sites of coagulation factor IX-binding protein

Coagulation factor IX-binding protein, isolated from Trimeresurus flavoviridis (IX-bp), is a C-type lectin-like protein. It is an anticoagulant consisting of homologous subunits, A and B. Each subunit has a Ca(2+)-binding site with a unique affinity (K(d) values of 14muM and 130muM at pH 7.5). These binding characteristics are pH-dependent and, under acidic conditions, the Ca(2+) binding of the low-affinity site was reduced considerably. In order to identify which site has high affinity and to investigate the pH-dependent Ca(2+) release mechanism, we have determined the crystal structures of IX-bp at pH 6.5 and pH 4.6 (apo form), and compared the Ca(2+)-binding sites with each other and with those of the solved structures under alkaline conditions; pH 7.8 and pH 8.0 (complexed form). At pH 6.5, Glu43 in the Ca(2+)-binding site of subunit A displayed two conformations. One (minor) is that in the alkaline state, and the other (major) is that at pH 4.6. However, the corresponding Gln43 residue of subunit B is in only a single conformation, which is almost identical with that in the alkaline state. At pH 4.6, Glu43 of subunit A adopts a conformation similar to that of the major conformer observed at pH 6.5, while Gln43 of subunit B assumes a new conformation, and both Ca(2+) positions are occupied by water molecules. These results showed that Glu43 of subunit A is much more sensitive to protonation than Gln43 of subunit B, and the conformational change of Glu43 occurs around pH6.5, which may correspond to the step of Ca(2+) release.     

Love–Hate ligands for high resolution analysis of strain in ultra-stable protein/small molecule interaction

The pathway of ligand dissociation and how binding sites respond to force are not well understood for any macromolecule. Force effects on biological receptors have been studied through simulation or force spectroscopy, but not by high resolution structural experiments. To investigate this challenge, we took advantage of the extreme stability of the streptavidin–biotin interaction, a paradigm for understanding non-covalent binding as well as a ubiquitous research tool. We synthesized a series of biotin-conjugates having an unchanged strong-binding biotin moiety, along with pincer-like arms designed to clash with the protein surface: ‘Love–Hate ligands’. The Love–Hate ligands contained various 2,6-di-ortho aryl groups, installed using Suzuki coupling as the last synthetic step, making the steric repulsion highly modular. We determined binding affinity, as well as solving 1.1–1.6 Å resolution crystal structures of streptavidin bound to Love–Hate ligands. Striking distortion of streptavidin’s binding contacts was found for these complexes. Hydrogen bonds to biotin’s ureido and thiophene rings were preserved for all the ligands, but biotin’s valeryl tail was distorted from the classic conformation. Streptavidin’s L3/4 loop, normally forming multiple energetically-important hydrogen bonds to biotin, was forced away by clashes with Love–Hate ligands, but Ser45 from L3/4 could adapt to hydrogen-bond to a different part of the ligand. This approach of preparing conflicted ligands represents a direct way to visualize strained biological interactions and test protein plasticity.     

Genetic engineering of streptavidin,a versatile affinity tag

Streptavidin, a tetrameric protein produced by Streptomyces avidinii, has been used as a useful, versatile affinity tag in a variety of biological applications. The efficacy of streptavidin is derived from its extremely high binding affinity for the vitamin biotin. For the last several years, we have used genetic engineering as a primary means to enhance the properties of streptavidin and to expand the application of streptavidin as an affinity tag. In this review, we describe several genetically engineered streptavidin variants, which include a streptavidin with a reduced biotin-binding affinity, a dimeric streptavidin, and a fusion protein between streptavidin and protein A, along with their potential applications in biological science.     

Structure of bovine beta-lactoglobulin at 6A resolution.

Bovine β-lactoglobulin is a dimer with a molecular weight of 2 × 18,400. In solution it undergoes a pH-dependent transition at pH 7.0 between two alternative structures, named N and R. The structures of four different crystal forms have been determined by multiple isomorphous replacement with heavy-atoms. Two of them, lattices K and X, were crystallised at pH 6.5, corresponding to the N state in solution; and the other two, lattices Y and Z, were crystallised at pH 7.5, corresponding to the R state in solution. The figures of merit of the phase angles determined for these lattices were 0.76, 0.77, 0.80 and 0.80, respectively. The four structures that emerged are similar and show certain features suggestive of α-helices and pleated sheets, but the resolution is insufficient to trace the entire course of the polypeptide chain. No clear distinction can yet be made between the structures above or below pH 7.0, nor between the native molecule and the molecule from which the C-terminal leucine and histidine residues have been cleaved. Analyses at higher resolution are in progress.     

Enhancement of the sensitivity of surface plasmon resonance (SPR) immunosensor for the detection of anti-GAD antibody by changing the pH for streptavidin immobilization

Surface plasmon resonance (SPR) immunobiosensor was developed for the detection of anti-glutamic acid decarboxylase (GAD) antibody. In this study, carboxylic terminated self-assembled monolayer, which was prepared by mixing of 3-mercaptopropionic acid (3-MPA) and 11-mercaptoundecanoic acid (11-MUA) (10:1 ratio), was used to evaluate the effect of external pH on the affinity between streptavidin and sensor surface. At pH values ranging from 4.0 to 5.5, it was found that streptavidin could more easily access onto the sensor surface at higher pH, and the enhanced binding of streptavidin at high pH allowed more extensive immobilization of biotin-GAD, which serves as the epitope for anti-GAD antibody. Consequently, the increase of RU caused by immuno-response between GAD and anti-GAD antibody was remarkably higher when streptavidin was bound on to the sensor surface at pH 5.5 than at pH 4.5. Therefore, we could conclude that the pH of coupling buffer greatly influences the sensitivity of immunosensor.     

Fe2+ binding to apo and holo mammalian ferritin

The binding of Fe2+ to both apo and holo mammalian ferritin has been investigated under anaerobic conditions as a function of pH. In the pH range 6.0-7.5, 8.0 +/- 0.5 Fe2+ ions bind to each apoferritin molecule, but above pH 7.5, a pH-dependent Fe2+ binding profile is observed with up to 80 Fe2+ ions binding at pH 10.0. This Fe2+ binding is reversible and is accompanied by up to two H+ being released per Fe2+ bound at pH 10.0. The Fe2+ binding to apoferritin probably occurs in the 3-fold channels. A much larger and more complex pH-dependent Fe2+ binding stoichiometry was observed for holoferritin with up to 300 Fe2+ ions binding at pH 10.0. This pH-dependent Fe2+ binding was interpreted as Fe2+ interaction at the FeOOH mineral surface with displacement of H+ from -OH or phosphate surface groups by the incoming Fe2+ ions. Mossbauer spectroscopic measurements using 57Fe-labeled Fe2+ under anaerobic conditions showed that 57Fe2+ binding to holoferritin was accompanied by electron transfer to the core, yielding 57Fe3+, presumably bound to the mineral surface. Removal of added iron by Fe2+-specific chelating agents yielded 57Fe2+, demonstrating the reversibility of this electron-transfer process. The Fe2+ bound to apo- and holoferritin is readily converted to Fe3+ by exposure to O2 and strongly retained by the respective ferritin species.     

Chicken avidin exhibits pseudo-catalytic properties. Biochemical, structural, and electrostatic consequences

Avidin and its bacterial analogue streptavidin exhibit similarly high affinities toward the vitamin biotin. The extremely high affinity of these two proteins has been utilized as a powerful tool in many biotechnological applications. Although avidin and streptavidin have similar tertiary and quaternary structures, they differ in many of their properties. Here we show that avidin enhances the alkaline hydrolysis of biotinyl p-nitrophenyl ester, whereas streptavidin protects this reaction even under extreme alkaline conditions (pH > 12). Unlike normal enzymatic catalysis, the hydrolysis reaction proceeds as a single cycle with no turnover because of the extremely high affinity of the protein for one of the reaction products (i.e. free biotin). The three-dimensional crystal structures of avidin (2 A) and streptavidin (2.4 A) complexed with the amide analogue, biotinyl p-nitroanilide, as a model for the p-nitrophenyl ester, revealed structural insights into the factors that enhance or protect the hydrolysis reaction. The data demonstrate that several molecular features of avidin are responsible for the enhanced hydrolysis of biotinyl p-nitrophenyl ester. These include the nature of a decisive flexible loop, the presence of an obtrusive arginine 114, and a newly formed critical interaction between lysine 111 and the nitro group of the substrate. The open conformation of the loop serves to expose the substrate to the solvent, and the arginine shifts the p-nitroanilide moiety toward the interacting lysine, which increases the electron withdrawing characteristics and consequent electrophilicity of the carbonyl group of the substrate. Streptavidin lacked such molecular properties, and analogous interactions with the substrate were consequently absent. The information derived from these structures may provide insight into the action of artificial protein catalysts and the evolution of catalytic sites in general.     

Streptavidin contains an RYD sequence which mimics the RGD receptor domain of fibronectin

Streptavidin binds at low levels and high affinity to cell surfaces, the cause of which can be traced to the occurrence of a sequence containing RYD (Arg-Tyr-Asp) in the protein molecule. This binding is enhanced in the presence of biotin. Cell-bound streptavidin can be displaced by fibronectin, as well as by RGD- and RYD-containing peptides. In addition, streptavidin can displace fibronectin from cell surfaces. The RYD sequence of streptavidin thus mimics RGD (Arg-Gly-Asp), the universal recognition domain present in fibronectin and other adhesion-related molecules. The observed adhesion to cells has no relevance to biotin-binding since the RYD sequence is not part of the biotin-binding site of streptavidin. Since the use of streptavidin in avidin-biotin technology is based on its biotin-binding properties, researchers are hereby warned against its indiscriminate use in histochemical and cytochemical studies.