Visualization of beta-sheets and side-chain clusters in two-dimensional periodic arrays of streptavidin on phospholipid monolayers by electron crystallography.

The biotin-binding protein streptavidin was crystallized as two-dimensional periodic arrays on biotinylated phospholipid monolayers. Electron diffraction patterns and images of the arrays embedded in vitreous ice were recorded to near-atomic resolution. Amplitudes and phases of structure factors were computed and combined to produce a 3 A projection density map. The reliability of the map was verified by comparing it to the available x-ray atomic model of the molecule. Projection densities from beta-strands and some amino acid side chains were identified from the electron cryomicroscopy map. These results demonstrate the first near-atomic image of this type of protein periodic array by electron crystallography, which has a great potential to aid in the structural characterization of molecular arrays engineered on a monolayer for various basic or biotechnological applications.     

Two-dimensional crystallization of avidin on biotinylated lipid monolayers.

Two-dimensional crystals of avidin were obtained on mixed lipid monolayers containing biotinylated lipids (N-biotinyl-dipalmitoyl-L-alpha-phosphatidyl ethanolamine and dioleoyl phosphatidyl choline) by specific interaction. Image analysis of electron micrographs of these crystals revealed p2 symmetry with the unit cell parameters a = 66 +/- 2 A, b = 68 +/- 1 A, and gamma = 121 +/- 4 degrees. The projection map showed, at a resolution of about 27 A, that the four subunits within one avidin molecule are separated into two parts. Comparison between avidin and streptavidin reveals that avidin molecule binds to the lipid monolayer in an orientation similar to that of streptavidin.     

Crystallographic data for Streptomyces avidinii streptavidin

Crystallization conditions are reported for Streptomyces avidinii streptavidin with and without bound biotin. X-ray examination of the free and bound crystal forms shows the streptavidin-biotin complex crystals to be most suitable for high resolution structure analysis. A complete x-ray data set to 2.6 A resolution was collected for the streptavidin-biotin crystals using a two-dimensional area detector. Reduction and analysis of the x-ray diffraction pattern show that the complex crystallizes in the tetragonal space group I4(1)22 (a = b = 98.4 A, c = 125.8 A), with half of the streptavidin tetramer in the crystallographic asymmetric unit.     

Affinity thermoprecipitation and recovery of biotinylated biomolecules via a mutant streptavidin-smart polymer conjugate

A system has been developed for reversibly binding and thermoprecipitating biotinylated macromolecules. A high off-rate Ser45Ala (S45A) streptavidin mutant has been covalently conjugated to poly(N-isopropylacrylamide) (PNIPAAm), a temperature-responsive polymer. The resulting conjugate is shown to coprecipitate biotinylated immunoglobulin G (IgG) and a biotinylated oligonucleotide in response to a thermal stimulus. Thermally precipitated biotinylated macromolecules can be released from the S45A-PNIPAAm conjugate by simple treatment with excess free biotin. This release step has been shown to be unique to the mutant streptavidin conjugate-a conjugate of wild type (WT) streptavidin and PNIPAAm does not release bound biotinylated molecules upon treatment with excess free biotin. The capture efficiency (fraction of target molecule precipitated from solution) of the S45A-PNIPAAm conjugate is similar to that of the WT-PNIPAAm conjugate for the biotinylated IgG target molecule (near 100%), but significantly smaller for the biotinylated oligonucleotide target (approximately 60% for the S45A-PNIPAAm conjugate compared to 80% for the WT-PNIPAAm conjugate). The release efficiency (fraction of originally precipitated target molecule released after treatment with free biotin) of the S45A-PNIPAAm conjugate is 70-80% for the biotinylated IgG target and nears 100% for the biotinylated oligonucleotide target. This system demonstrates the use of a high off-rate streptavidin mutant to add reversibility to a system based on smart-polymer-streptavidin conjugates.     

Purification of biotinylated proteins on streptavidin resin: a protocol for quantitative elution

The interaction between streptavidin and biotin is one of the most widely used tools in chemistry and biology. However, the release of biotinylated proteins from streptavidin resins remains a major problem, due to the extraordinary stability of this complex. We present a new protocol for the quantitative elution of biotinylated proteins from streptavidin Sepharose, featuring harsh elution conditions and competition with free biotin. The usefulness of the method was demonstrated by the quantitative recovery of biotinylated proteins from organ homogenates, obtained from mice perfused with a reactive ester derivative of biotin.     

Uptake by macrophages of a biotinylated oligo-alpha-deoxythymidylate by using mannosylated streptavidin.

Streptavidin substituted with mannose residues increased by 20-fold the intracellular concentration of a biotinylated dodecakis(alpha-deoxythymidylate) in macrophages by comparison with the uptake of free oligodeoxynucleotide. Streptavidin, the bacterial homologue of the very basic avidin, which does not contain any carbohydrate moieties and is a neutral protein, was substituted with 12 mannose residues in order to be recognized and internalized by mannose-specific lectins on the surface of macrophages. A 3'-biotinylated and 5'-fluoresceinylated dodecakis (alpha-deoxythymidylate) was synthesized and bound onto mannosylated streptavidin. The conjugate was isolated, and by using flow cytometry, it was shown that the uptake of fluoresceinylated oligodeoxynucleotides bound to mannosylated streptavidin by macrophages is 20-fold higher than that of free oligodeoxynucleotides and that the uptake was competively inhibited by mannosylated serum albumin. Glycosylated streptavidin conjugates recognizing specific membrane lectins on different cells provide the possibility to target biotinylated antisense oligodeoxynucleotides and to increase the biological effect of these chemotherapeutic agents.     

Streptavidin-induced lysis of homologous biotinylated erythrocytes. Evidence against the key role of the avidin charge in complement activation via the alternative pathway

It is shown that non-covalent attachment of streptavidin, as well as of avidin, to biotinylated human erythrocytes induces homologous hemolysis by complement. Rabbit antiserum against human C3 is found to inhibit the lysis specifically as compared with non-immune rabbit serum. Efficiency of lysis inhibition is greater for avidin- and streptavidin-induced lysis of biotinylated human erythrocytes than for antibody-sensitized sheep erythrocytes. In contrast to positively charged avidin (pI 11), streptavidin is a neutral protein. Hence, hemolysis of streptavidin-carrying erythrocytes is inconsistent with the suggestion on the crucial role of avidin charge in lysis. Membrane alterations (cross-linking and clusterization of biotinylated components) induced by avidin (streptavidin) seem to be a more plausible explanation for the lysis.     

Hybrid selection of mRNA with biotinylated DNA

A novel, convenient, and highly efficient hybrid selection procedure is described. The method utilizes the polymerase chain reaction (PCR) in which one of two primers is biotinylated at the 5'-terminus. The concentration of the biotinylated primer is 100 times that of the other to synthesize biotinylated single-stranded DNA (asymmetric PCR). After hybridization of the biotinylated DNA with mRNA in solution, streptavidin agarose is used to trap the hybrid duplex of mRNA.DNA-biotin onto the solid matrix. The selected mRNA is then eluted from the streptavidin agarose. The quantitative physical recovery of selected mRNA is about 70% with about 33% retention of biological activity.     

Quantitative comparison of zero-loss and conventional electron diffraction from two-dimensional and thin three-dimensional protein crystals

The scattering cross-section of atoms in biological macromolecules for both elastically and inelastically scattered electrons is approximately 100,000 times larger than that for x-ray. Therefore, much smaller (<1 microm) and thinner (<0.01 microm) protein crystals than those used for x-ray crystallography can be used to analyze the molecular structures by electron crystallography. But, inelastic scattering is a serious problem. We examined electron diffraction data from thin three-dimensional (3-D) crystals (600-750 A thick) and two-dimensional (2-D) crystals (approximately 60 A thick), both at 93 K, with an energy filtering electron microscope operated at an accelerating voltage of 200 kV. Removal of inelastically scattered electrons significantly improved intensity data statistics and R(Friedel) factor in every resolution range up to 3-A resolution. The effect of energy filtering was more prominent for thicker crystals but was significant even for thin crystals. These filtered data sets showed better intensity statistics even in comparison with data sets collected at 4 K and an accelerating voltage of 300 kV without energy filtering. Thus, the energy filter will be an effective and important tool in the structure analysis of thin 3-D and 2-D crystals, particularly when data are collected at high tilt angle.     

A sensitive enzyme assay for biotin, avidin, and streptavidin

Reciprocal enzyme assays are described for the vitamin biotin and for the biotin-binding proteins avidin and streptavidin. The assays are based on the following steps: (a) biotinylated bovine serum albumin is adsorbed onto microtiter plates; (b) streptavidin (or avidin) is bound to the biotin-coated plates; (c) biotinylated enzyme (in this case alkaline phosphatase) is then interacted with the free biotin-binding sites on the immobilized protein. For biotin assay, competition between the free vitamin and the biotinylated enzyme is carried out between steps (b) and (c). The method takes advantage of the four biotin-binding sites which characterize both avidin and streptavidin. The method is extremely versatile and accurate over a concentration range exceeding three orders of magnitude. The lower limits of detection are approximately 2 pg/ml (0.2 pg/sample) for biotin and less than 100 ng/ml (10 ng/sample) for either avidin or streptavidin.     

Efficient and versatile one-step affinity purification of in vivo biotinylated proteins: expression, characterization and structure analysis of recombinant human glutamate carboxypeptidase II

Affinity purification is a useful approach for purification of recombinant proteins. Eukaryotic expression systems have become more frequently used at the expense of prokaryotic systems since they afford recombinant eukaryotic proteins with post-translational modifications similar or identical to the native ones. Here, we present a one-step affinity purification set-up suitable for the purification of secreted proteins. The set-up is based on the interaction between biotin and mutated streptavidin. Drosophila Schneider 2 cells are chosen as the expression host, and a biotin acceptor peptide is used as an affinity tag. This tag is biotinylated by Escherichia coli biotin-protein ligase in vivo. We determined that localization of the ligase within the ER led to the most effective in vivo biotinylation of the secreted proteins. We optimized a protocol for large-scale expression and purification of AviTEV-tagged recombinant human glutamate carboxypeptidase II (Avi-GCPII) with milligram yields per liter of culture. We also determined the 3D structure of Avi-GCPII by X-ray crystallography and compared the enzymatic characteristics of the protein to those of its non-tagged variant. These experiments confirmed that AviTEV tag does not affect the biophysical properties of its fused partner. Purification approach, developed here, provides not only a sufficient amount of highly homogenous protein but also specifically and effectively biotinylates a target protein and thus enables its subsequent visualization or immobilization.     

Advances in structural and functional analysis of membrane proteins by electron crystallography

Electron crystallography is a powerful technique for the study of membrane protein structure and function in the lipid environment. When well-ordered two-dimensional crystals are obtained the structure of both protein and lipid can be determined and lipid-protein interactions analyzed. Protons and ionic charges can be visualized by electron crystallography and the protein of interest can be captured for structural analysis in a variety of physiologically distinct states. This review highlights the strengths of electron crystallography and the momentum that is building up in automation and the development of high throughput tools and methods for structural and functional analysis of membrane proteins by electron crystallography.     

Fragment-based phase extension for three-dimensional structure determination of membrane proteins by electron crystallography

In electron crystallography, membrane protein structure is determined from two-dimensional crystals where the protein is embedded in a membrane. Once large and well-ordered 2D crystals are grown, one of the bottlenecks in electron crystallography is the collection of image data to directly provide experimental phases to high resolution. Here, we describe an approach to bypass this bottleneck, eliminating the need for high-resolution imaging. We use the strengths of electron crystallography in rapidly obtaining accurate experimental phase information from low-resolution images and accurate high-resolution amplitude information from electron diffraction. The low-resolution experimental phases were used for the placement of α helix fragments and extended to high resolution using phases from the fragments. Phases were further improved by density modifications followed by fragment expansion and structure refinement against the high-resolution diffraction data. Using this approach, structures of three membrane proteins were determined rapidly and accurately to atomic resolution without high-resolution image data.     

Two-dimensional crystallization of streptavidin by nonspecific binding to a surface film: study with a scanning electron microscope.

A two-dimensional (2D) crystal of streptavidin has been obtained by a nonspecific binding method. The protein molecules were bound and formed a dense packing on the film of poly(1-benzyl-L-histidine) spread at the surface of protein solution. The surface film was moderately heated to stimulate crystallization of bound streptavidin. A potential of this method for obtaining 2D crystals of soluble proteins is demonstrated. The present 2D crystal structure of streptavidin resembles that previously obtained by specific binding to biotinylated lipid. We show in addition that the 2D array of protein with usual size approximately 50 A can be imaged using a high resolution scanning electron microscope (HR-SEM) and subject to structural analysis at low resolution. Various limitations in HR-SEM degrade considerably the image quality. However, the usability of a bulk plate as specimen support would make HR-SEM a convenient tool, when such a substrate must be considered in application of protein arrays, and if an intrinsic low resolution is acceptable.     

Proteomic analysis of the androgen receptor via MS-compatible purification of biotinylated protein on streptavidin resin

The strength of the streptavidin/biotin interaction poses challenges for the recovery of biotinylated molecules from streptavidin resins. As an alternative to high-temperature elution in urea-containing buffers, we show that mono-biotinylated proteins can be released with relatively gentle heating in the presence of biotin and 2% SDS/Rapigest, avoiding protein carbamylation and minimizing streptavidin dissociation. We demonstrate the utility of this mild elution strategy in two studies of the human androgen receptor (AR). In the first, in which formaldehyde cross-linked complexes are analyzed in yeast, a mass spectrometry-based comparison of the AR complex using SILAC reveals an association between the androgen-activated AR and the Hsp90 chaperonin, while Hsp70 chaperonins associate specifically with the unliganded complex. In the second study, the endogenous AR is quantified in the LNCaP cell line by absolute SILAC and MRM-MS showing approximately 127,000 AR copies per cell, substantially more than previously measured using radioligand binding.     

Characterization and application of a surface modification designed for QCM-D studies of biotinylated biomolecules

The rapid development of surface sensitive biosensor technologies, especially towards nanoscale devices, requires increasing control of surface chemistry to provide reliable and reproducible results, but also to take full advantage of the sensing opportunities. Here, we present a surface modification strategy to allow biotinylated biomolecules to be immobilized to gold coated sensor crystals for quartz crystal microbalance with dissipation monitoring (QCM-D) sensing. The unique feature of QCM-D is its sensitivity to nanomechanical (viscoelastic) properties at the sensing interface. The surface modification was based on mixed monolayers of oligo(ethylene glycol) (OEG) disulfides, with terminal -OH or biotin groups, on gold. Mixtures containing 1% of the biotin disulfide were concluded to be the most appropriate based on the performance when streptavidin was immobilized to biotinylated sensors and the subsequent biotinylated bovine serum albumin (BSA) interaction was studied. The OEG background kept the unspecific protein binding to a minimum, even when subjected to serum solutions with a high protein concentration. Based on characterization by contact angle goniometry, ellipsometry, and infrared spectroscopy, the monolayers were shown to be well-ordered, with the OEG chains predominantly adopting a helical conformation but also partly an amorphous structure. Storage stability was concluded to depend mainly on light exposure while almost all streptavidin binding activity was retained when storing the sensors cold and dark for 8 weeks. The surface modification was also tested for repeated antibody-antigen interactions between BSA and anti-BSA (immobilized to biotinylated protein A) in QCM-D measurements lasting for >10h with intermediate basic regeneration. This proved an excellent stability of the coating and good reproducibility was obtained for 5 interaction cycles. With this kind of generic surface modification QCM-D can be used in a variety of biosensing applications to provide not only mass but also relevant information of the structural properties of adlayers.     

Avidin-induced lysis of biotinylated erythrocytes by homologous complement via the alternative pathway depends on avidin's ability of multipoint binding with biotinylated membrane.

It was reported that avidin and streptavidin induce lysis of prebiotinylated red blood cells via the alternative pathway of both homologous and heterologous complement. Both of these proteins have four biotin-binding sites, providing a polyvalent interaction with biotinylated components of the erythrocyte membrane. We have compared the effects of mono- and multipoint avidin attachment on the sensitivity of biotinylated erythrocytes to lysis by the complement system. In the presence of anti-avidin antibody, avidin-bearing biotinylated erythrocytes were rapidly lysed by heterologous serum. This lysis was independent from the mode of avidin attachment, implying that complement activation by the classical pathway triggered by interaction between C1 and avidin-bound antibody on the erythrocyte surface is independent from the avidin's ability of polyvalent (multipoint) binding with biotinylated membrane components. In the absence of anti-avidin antibody, biotinylated erythrocytes bearing polyvalently attached avidin were lysed by homologous complement better than cells bearing avidin, which possesses reduced ability for multipoint binding with biotinylated erythrocyte. Two independent approaches to reduce avidin's ability of multipoint binding were used: decrease in surface density of biotin on the erythrocyte membrane and blockage of biotin-binding sites of avidin. Both methods result in reduced lysis of avidin-bearing erythrocytes as compared with erythrocytes bearing an equal amount of polyvalent-bound avidin. Thus the activation of homologous complement via the alternative pathway depends on avidin's ability to 'cross-link' to the biotinylated components of the erythrocyte membrane.     

Affinity chromatography of DNA labeled with chemically cleavable biotinylated nucleotide analogs

DNA labeled with the chemically cleavable biotinylated nucleotide Bio-12-SS-dUTP was chromatographed on biotin cellulose affinity columns using either avidin or streptavidin as the affinity reagent. Although both proteins were equally effective in binding the Bio-12-SS-DNA to the affinity resin, two important differences were found. First, nonbiotinylated DNA bound to avidin, but not to streptavidin, in buffers containing 50 mM NaCl. Second, Bio-12-SS-DNA was released much more slowly from the streptavidin affinity column than from the avidin column upon washing with buffer containing dithiothreitol. This difficulty in reducing the disulfide bond of Bio-12-SS-DNA bound to streptavidin is most likely due to steric protection of the disulfide bond by the protein. This conclusion is supported by our finding that DNA labeled with another biotinylated nucleotide analog, Bio-19-SS-dUTP, is rapidly and efficiently recovered from a streptavidin column. In Bio-19-SS-DNA, the distance between the disulfide bond and the biotin group is approximately 10 A greater than that in Bio-12-SS-DNA. Therefore, Bio-19-SS-dUTP and streptavidin form the basis of an efficient affinity system for the isolation and subsequent recovery of biotinylated DNA in the presence of low ionic strength buffers.     

Effect of streptavidins with varying biotin binding affinities on the properties of biotinylated gramicidin channels

The pentadecapeptide gramicidin A, which is known to form highly conductive ion channels in a bilayer lipid membrane by assembling as transmembrane head-to-head dimers, can be modified by attaching a biotin group to its C-terminus through an aminocaproyl spacer. Such biotinylated gramicidin A analogues also form ion channels in a hydrophobic lipid bilayer, exposing the biotin group to the aqueous bathing solution. Interaction of the biotinylated gramicidin channels with (strept)avidin has previously been shown to result in the appearance of a long-lasting open state with a doubled transition amplitude in single-channel traces and a deceleration of the macroscopic current kinetics as studied by the sensitized photoinactivation method. Here this interaction was studied further by using streptavidin mutants with weakened biotin binding affinities. The Stv-F120 mutant, having a substantially reduced biotin binding affinity, exhibited an efficacy similar to that of natural streptavidin in inducing both double-conductance channel formation and deceleration of the photoinactivation kinetics of the biotinylated gramicidin having a long linker arm. The Stv-A23D27 mutant with a severely weakened biotin binding affinity was ineffective in eliciting the double-conductance channels, but decelerated noticeably the photoinactivation kinetics of the long linker biotinylated gramicidin. However, the marked difference in the effects of the mutant and natural streptavidins was smaller than expected on the basis of the substantially reduced biotin binding affinity of the Stv-A23D27 mutant. This may suggest direct interaction of this mutant streptavidin with a lipid membrane in the process of its binding to biotinylated gramicidin channels. The role of linker arm length in the interaction of biotinylated gramicidins with streptavidin was revealed in experiments with a short linker gramicidin. This gramicidin analogue appeared to be unable to form double-conductance channels, though several lines of evidence were indicative of its binding by streptavidin. The data obtained show the conditions under which the interaction of streptavidin with biotinylated gramicidin leads to the formation of the double-conductance tandem channels composed of two cross-linked transmembrane dimers.