Rhizavidin from Rhizobium etli: the first natural dimer in the avidin protein family

Rhizobium etli CFN42 is a symbiotic nitrogen-fixing bacterium of the common bean Phaseolus vulgaris. The symbiotic plasmid p42d of R. etli comprises a gene encoding a putative (strept)avidin-like protein, named rhizavidin. The amino acid sequence identity of rhizavidin in relation to other known avidin-like proteins is 20-30%. The amino acid residues involved in the (strept)avidin-biotin interaction are well conserved in rhizavidin. The structural and functional properties of rhizavidin were carefully studied, and we found that rhizavidin shares characteristics with bradavidin, streptavidin and avidin. However, we found that it is the first naturally occurring dimeric protein in the avidin protein family, in contrast with tetrameric (strept)avidin and bradavidin. Moreover, it possesses a proline residue after a flexible loop (GGSG) in a position close to Trp-110 in avidin, which is an important biotin-binding residue. [3H]Biotin dissociation and ITC (isothermal titration calorimetry) experiments showed dimeric rhizavidin to be a high-affinity biotin-binding protein. Its thermal stability was lower than that of avidin; although similar to streptavidin, it was insensitive to proteinase K. The immunological cross-reactivity of rhizavidin was tested with human serum samples obtained from cancer patients exposed to (strept)avidin. No significant cross-reactivity was observed. The biodistribution of the protein was studied by SPECT (single-photon emission computed tomography) imaging in rats. Similarly to avidin, rhizavidin was observed to accumulate rapidly, mainly in the liver. Evidently, rhizavidin could be used as a complement to (strept)avidin in (strept)avidin-biotin technology.     

The highly dynamic oligomeric structure of bradavidin II is unique among avidin proteins

Bradavidin II is a biotin‐binding protein from Bradyrhizobium japonicum that resembles chicken avidin and bacterial streptavidin. A biophysical characterization was carried out using dynamic light scattering, native mass spectrometry, differential scanning calorimetry, and isothermal titration calorimetry combined with structural characterization using X‐ray crystallography. These observations revealed that bradavidin II differs from canonical homotetrameric avidin protein family members in its quaternary structure. In contrast with the other avidins, bradavidin II appears to have a dynamic (transient) oligomeric state in solution. It is monomeric at low protein concentrations but forms higher oligomeric assemblies at higher concentrations. The crystal structure of bradavidin II revealed an important role for Phe42 in shielding the bound ligand from surrounding water molecules, thus functionally replacing the L7,8 loop essential for tight ligand binding in avidin and streptavidin. This bradavidin II characterization opens new avenues for oligomerization‐independent biotin‐binding protein development.     

Novel avidin-like protein from a root nodule symbiotic bacterium, Bradyrhizobium japonicum

Bradyrhizobium japonicum is an important nitrogenfixing symbiotic bacterium, which can form root nodules on soybeans. These bacteria have a gene encoding a putative avidin- and streptavidin-like protein, which bears an amino acid sequence identity of only about 30% over the core regions with both of them. We produced this protein in Escherichia coli both as the full-length wild type and as a C-terminally truncated core form and showed that it is indeed a high affinity biotin-binding protein that resembles (strept)avidin structurally and functionally. Because of the considerable dissimilarity in the amino acid sequence, however, it is immunologically very different, and polyclonal rabbit and human antibodies toward (strept)avidin did not show significant cross-reactivity with it. Therefore this new avidin, named bradavidin, facilitates medical treatments such as targeted drug delivery, gene therapy, and imaging by offering an alternative tool for use if (strept)avidin cannot be used, because of a deleterious patient immune response for example. In addition to its medical value, bradavidin can be used both in other applications of avidin-biotin technology and as a source of new ideas when creating engineered (strept)avidin forms by changing or combining the desired parts, interface patterns, or specific residues within the avidin protein family. Moreover, the unexpected discovery of bradavidin indicates that the group of new and undiscovered bacterial avidin-like proteins may be both more diverse and more common than hitherto thought.     

Studies on the biotin-binding sites of avidin and streptavidin. A chemically induced dynamic nuclear polarization investigation of the status of tyrosine residues.

We applied the protein photochemically induced dynamic nuclear polarization (photo-c.i.d.n.p.) method to explore the conformation of the side chains of tyrosine, tryptophan and histidine residues in three biotin-binding proteins. The c.i.d.n.p. spectra of avidin, streptavidin and 'core' streptavidin were compared with those of their complexes with biotin and its derivatives. The data indicate that the single tyrosine residue (Tyr-33) of avidin is clearly inaccessible to the triplet flavin photo-c.i.d.n.p. probe. The same holds for all tryptophan and histidine side chains. Although the analogous Tyr-43 residue of streptavidin is also buried, at least three of the other tyrosine residues of this protein are exposed. The same conclusions apply to the truncated form of the protein, core streptavidin. As judged by the photo-c.i.d.n.p. results, complexing of avidin and streptavidin with biotin, N-epsilon-biotinyl-L-lysine (biocytin) or biotinyltyrosine has little or no effect on tyrosine accessibility in these proteins. Biotinyltyrosine can be used to probe the depth of the corresponding binding site. The accessibility of the tyrosine side chain of biotinyltyrosine in the complex demonstrates the exquisite fit of the biotin-binding cleft of avidin: only the biotin moiety appears to be accommodated, leaving the tyrosine side chain exposed.     

UV resonance Raman study of streptavidin binding of biotin and 2-iminobiotin: comparison with avidin

UV resonance Raman (UVRR) spectroscopy is used to study the binding of biotin and 2-iminobiotin by streptavidin, and the results are compared to those previously obtained from the avidin-biotin complex and new data from the avidin-2-iminobiotin complex. UVRR difference spectroscopy using 244-nm excitation reveals changes to the tyrosine (Tyr) and tryptophan (Trp) residues of both proteins upon complex formation. Avidin has four Trp and only one Tyr residue, while streptavidin has eight Trp and six Tyr residues. The spectral changes observed in streptavidin upon the addition of biotin are similar to those observed for avidin. However, the intensity enhancements observed for the streptavidin Trp Raman bands are less than those observed with avidin. The changes observed in the streptavidin Tyr bands are similar to those observed for avidin and are assigned exclusively to the binding site Tyr 43 residue. The Trp and Tyr band changes are due to the exclusion of water and addition of biotin, resulting in a more hydrophobic environment for the binding site residues. The addition of 2-iminobiotin results in spectral changes to both the streptavidin and avidin Trp bands that are very similar to those observed upon the addition of biotin in each protein. The changes to the Tyr bands are very different than those observed with the addition of biotin, and similar spectral changes are observed in both streptavidin and avidin. This is attributable to hydrogen bond changes to the binding site Tyr residue in each protein, and the similar Tyr difference features in both proteins supports the exclusive assignment of the streptavidin Tyr difference features to the binding site Tyr 43.     

An avidin-like domain that does not bind biotin is adopted for oligomerization by the extracellular mosaic protein fibropellin

The protein avidin found in egg white seems optimized for binding the small vitamin biotin as a stable homotetramer. Indeed, along with its streptavidin ortholog in the bacterium Streptomyces avidinii, this protein shows the strongest known noncovalent bond of a protein with a small ligand. A third known member of the avidin family, as similar to avidin as is streptavidin, is found at the C-terminal ends of the multidomain fibropellin proteins found in sea urchin. The fibropellins form a layer known as the apical lamina that surrounds the sea urchin embryo throughout development. Based upon the structure of avidin, we deduced a structural model for the avidin-like domain of the fibropellins and found that computational modeling predicts a lack of biotin binding and the preservation of tetramerization. To test this prediction we expressed and purified the fibropellin avidin-like domain and found it indeed to be a homotetramer incapable of binding biotin. Several lines of evidence suggest that the avidin-like domain causes the entire fibropellin protein to tetramerize. We suggest that the presence of the avidin-like domain serves a structural (tetrameric form) rather than functional (biotin-binding) role and may therefore be a molecular instance of exaptation-the modification of an existing function toward a new function. Finally, based upon the oligomerization of the avidin-like domain, we propose a model for the overall structure of the apical lamina.     

Dimer-tetramer transition between solution and crystalline states of streptavidin and avidin mutants

The biotin-binding tetrameric proteins, streptavidin from Streptomyces avidinii and chicken egg white avidin, are excellent models for the study of subunit-subunit interactions of a multimeric protein. Efforts are thus being made to prepare mutated forms of streptavidin and avidin, which would form monomers or dimers, in order to examine their effect on quaternary structure and assembly. In the present communication, we compared the crystal structures of binding site W-->K mutations in streptavidin and avidin. In solution, both mutant proteins are known to form dimers, but upon crystallization, both formed tetramers with the same parameters as the native proteins. All of the intersubunit bonds were conserved, except for the hydrophobic interaction between biotin and the tryptophan that was replaced by lysine. In the crystal structure, the binding site of the mutated apo-avidin contains 3 molecules of structured water instead of the 5 contained in the native protein. The lysine side chain extends in a direction opposite that of the native tryptophan, the void being partially filled by an adjacent lysine residue. Nevertheless, the binding-site conformation observed for the mutant tetramer is an artificial consequence of crystal packing that would not be maintained in the solution-phase dimer. It appears that the dimer-tetramer transition may be concentration dependent, and the interaction among subunits obeys the law of mass action.     

Novel circular dichroism spectroscopic approach for detection of ligand binding of proteins: Avidin as example

Various globular proteins having low or no α-helical content exhibit atypical far-ultraviolet (UV) circular dichroism (CD) spectra due to aromatic-aromatic residue and aromatic residue-peptide bond exciton coupling interactions. As a representative example of such proteins, far-UV CD spectra of chicken avidin were recorded before and after the addition of different small molecules. Intensity increase-decrease and/or wavelength shift of the positive CD peak of avidin at 228 nm were observed in the presence of various drugs, dyes, and natural compounds. The results were interpreted by exciton interactions between the aromatic residues of the biotin binding site and the substances bound to it. This novel, fast, microgram (μg) scale approach can be applied for detection of ligand binding of additional proteins displaying avidin-like far-UV CD spectra.     

Mutation of a critical tryptophan to lysine in avidin or streptavidin may explain why sea urchin fibropellin adopts an avidin-like domain

Sea urchin fibropellins are epidermal growth factor homologues that harbor a C-terminal domain, similar in sequence to hen egg-white avidin and bacterial streptavidin. The fibropellin sequence was used as a conceptual template for mutation of designated conserved tryptophan residues in the biotin-binding sites of the tetrameric proteins, avidin and streptavidin. Three different mutations of avidin, Trp-110-Lys, Trp-70-Arg and the double mutant, were expressed in a baculovirus-infected insect cell system. A mutant of streptavidin, Trp-120-Lys, was similarly expressed. The homologous tryptophan to lysine (W-->K) mutations of avidin and streptavidin were both capable of binding biotin and biotinylated material. Their affinity for the vitamin was, however, significantly reduced: from K(d) approximately 10(-15) M of the wild-type tetramer down to K(d) approximately 10(-8) M for both W-->K mutants. In fact, their binding to immobilized biotin matrices could be reversed by the presence of free biotin. The Trp-70-Arg mutant of avidin bound biotin very poorly and the double mutant (which emulates the fibropellin domain) failed to bind biotin at all. Using a gel filtration fast-protein liquid chromatography assay, both W-->K mutants were found to form stable dimers in solution. These findings may indicate that mimicry in the nature of the avidin sequence and fold by the fibropellins is not designed to generate biotin-binding, but may serve to secure an appropriate structure for facilitating dimerization.     

Studies on the biotin-binding site of streptavidin. Tryptophan residues involved in the active site.

Streptavidin, the non-glycosylated bacterial analogue of the egg-white glycoprotein avidin, was modified with the tryptophan-specific reagent 2-hydroxy-5-nitrobenzyl (Hnb) bromide. As with avidin, complete loss of biotin-binding activity was achieved upon modification of an average of one tryptophan residue per streptavidin subunit. Tryptic peptides obtained from an Hnb-modified streptavidin preparation were fractionated by reversed-phase h.p.l.c., and three major Hnb-containing peptide fractions were isolated. Amino acid and N-terminal sequence analysis revealed that tryptophan residues 92, 108 and 120 are modified and probably comprise part of the biotin-binding site of the streptavidin molecule. Unlike avidin, the modification of lysine residues in streptavidin failed to result in complete loss of biotin-binding activity. The data imply subtle differences in the fine structure of the respective biotin-binding sites of the two proteins.     

Engineering soluble monomeric streptavidin with reversible biotin binding capability

Monomeric streptavidin with reversible biotin binding capability has many potential applications. Because a complete biotin binding site in each streptavidin subunit requires the contribution of tryptophan 120 from a neighboring subunit, monomerization of the natural tetrameric streptavidin can generate streptavidin with reduced biotin binding affinity. Three residues, valine 55, threonine 76, and valine 125, were changed to either arginine or threonine to create electrostatic repulsion and steric hindrance at the interfaces. The double mutation (T76R,V125R) was highly effective to monomerize streptavidin. Because interfacial hydrophobic residues are exposed to solvent once tetrameric streptavidin is converted to the monomeric state, a quadruple mutein (T76R,V125R,V55T,L109T) was developed. The first two mutations are for monomerization, whereas the last two mutations aim to improve hydrophilicity at the interface to minimize aggregation. Monomerization was confirmed by four different approaches including gel filtration, dynamic light scattering, sensitivity to proteinase K, and chemical cross-linking. The quadruple mutein remained in the monomeric state at a concentration greater than 2 mg/ml. Its kinetic parameters for interaction with biotin suggest excellent reversible biotin binding capability, which enables the mutein to be easily purified on the biotin-agarose matrix. Another mutein (D61A,W120K) was developed based on two mutations that have been shown to be effective in monomerizing avidin. This streptavidin mutein was oligomeric in nature. This illustrates the importance in selecting the appropriate residues and approaches for effective monomerization of streptavidin.     

Easily reversible desthiobiotin binding to streptavidin,avidin, and other biotin-binding proteins: uses for protein labeling,detection, and isolation

The high-affinity binding of biotin to avidin, streptavidin, and related proteins has been exploited for decades. However, a disadvantage of the biotin/biotin-binding protein interaction is that it is essentially irreversible under physiological conditions. Desthiobiotin is a biotin analogue that binds less tightly to biotin-binding proteins and is easily displaced by biotin. We synthesized an amine-reactive desthiobiotin derivative for labeling proteins and a desthiobiotin-agarose affinity matrix. Conjugates labeled with desthiobiotin are equivalent to their biotinylated counterparts in cell-staining and antigen-labeling applications. They also bind to streptavidin and other biotin-binding protein-based affinity columns and are recognized by anti-biotin antibodies. Fluorescent streptavidin conjugates saturated with desthiobiotin, but not biotin, bind to a cell-bound biotinylated target without further processing. Streptavidin-based ligands can be gently stripped from desthiobiotin-labeled targets with buffered biotin solutions. Thus, repeated probing with fluorescent streptavidin conjugates followed by enzyme-based detection is possible. In all applications, the desthiobiotin/biotin-binding protein complex is easily dissociated under physiological conditions by either biotin or desthiobiotin. Thus, our desthiobiotin-based reagents and techniques provide some distinct advantages over traditional 2-iminobiotin, monomeric avidin, or other affinity-based techniques.     

Avidin-like domain in an epidermal growth factor homolog from a sea urchin

We have found that a protein from the purple sea urchin has a carboxyl-terminal domain with striking sequence similarity to chicken avidin and bacterial streptavidin. All our evidence supports the homology of these sequences. Tetramers of avidin and streptavidin bind biotin strongly; the biotin binding site involves two to four tryptophans and probably an adjacent lysine in each chain. The presence of four tryptophans at equivalent positions in the sea urchin protein domain suggests that it may also be able to bind biotin and inhibit cell growth, as do the two other proteins. Alternatively, this domain may have acquired a new role as part of a multidomain protein.     

A plasmid expression system for quantitative in vivo biotinylation of thioredoxin fusion proteins in Escherichia coli.

The high affinity binding interaction of biotin to avidin or streptavidin has been used widely in biochemistry and molecular biology, often in sensitive protein detection or protein capture applications. However, in vitro chemical techniques for protein biotinylation are not always successful, with some common problems being a lack of reaction specificity, inactivation of amino acid residues critical for protein function and low levels of biotin incorporation. This report describes an improved expression system for the highly specific and quantitative in vivo biotinylation of fusion proteins. A short 'biotinylation peptide', described previously by Schatz, is linked to the N-terminus of Escherichia coli thioredoxin (TrxA) to form a new protein, called BIOTRX. The 'biotinylation peptide' serves as an in vivo substrate mimic for E. coli biotin holoenzyme synthetase (BirA), an enzyme which usually performs highly selective biotinylation of E.coli biotin carboxyl carrier protein (BCCP). A plasmid expression vector carrying the BIOTRX and birA genes arranged as a bacterial operon can be used to obtain high level production of soluble BIOTRX and BirA proteins and, under appropriate culture conditions, BIOTRX protein produced by this system is completely biotinylated. Fusions of BIOTRX to other proteins or peptides, whether these polypeptides are linked to the C-terminus or inserted into the BIOTRX active site loop, are also quantitatively biotinylated. Both types of BIOTRX fusion can be captured efficiently on avidin/streptavidin media for purification purposes or to facilitate interaction assays. We illustrate the utility of the system by measurements of antibody and soluble receptor protein binding to BIOTRX fusions immobilized on streptavidin-conjugated BIAcore chips.     

Neoglycoproteins: preparation and properties of complexes of biotinylated asparagine-oligosaccharides with avidin and streptavidin

Neoglycoproteins in which the oligosaccharide moieties are attached noncovalently to the protein through a high-affinity ligand have been prepared from biotinylated oligosaccharides and avidin or the nonglycosylated microbial analogue streptavidin. One of the asparagine-oligosaccharides purified from Pronase-digested ovalbumin (Man6-GlcNAc2-Asn) was reacted with an excess of the hydroxysuccinimide ester of biotin or, for the purpose of quantitation, [3H]biotin. Derivatives were also prepared with an extension "arm", a 6-aminohexanoyl group, between biotin and asparagine. When the purified biotinyl-Asn-oligosaccharide was added to avidin or streptavidin, a complex was formed containing 3 mol of oligosaccharide/mol of protein. The complexes were stable at neutral pH in the absence of biotin and could be dialyzed for 2 weeks without any significant loss of ligand. In the presence of biotin, or under denaturing conditions, the oligosaccharide derivative was released and could be quantitatively recovered. To assess the influence of the protein matrix on the reactivity of the oligosaccharide units, free biotinyl-Asn-oligosaccharide and the corresponding avidin and streptavidin complexes were exposed to alpha-mannosidase in parallel experiments. The rate of hydrolysis of the free derivative was severalfold faster than that of the two protein complexes, and at the time when about 90% of the free derivative had all five alpha-mannosyl residues removed, the majority of the protein-bound derivatives contained two to four undigested alpha-mannosyl residues and also had a significant amount of undigested starting material. The ease of preparation and the properties of these neoglycoproteins suggest that they should be excellent models for the study of glycoprotein-receptor binding and glycoprotein processing.     

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.     

生物素化荧光素酶的克隆表达及其固定化研究

为了在体内实现萤火虫荧光素酶的生物素酰化修饰,我们将大肠杆菌中编码生物素羧基载体蛋白（biotin carboxyl carrier protein,BCCP）C端87个氨基酸的功能域基因融合到萤火虫(Pyrocoelia pectoralis)荧光素酶cDNA的末端。经大肠杆菌生物素合成酶（biotin holoenzyme synthetase）的催化,生物素与BCCP上特定的赖氨酸（Lys）残基共价结合,由此与BCCP融合的萤火虫荧光素酶间接实现了生物素化的修饰。利用生物素与配体亲和素或链霉亲和素的特异性耦合,可以将荧光素酶固定到亲和素或链霉亲和素包被的磁珠上,从而使荧光检测的应用更加灵活和方便。本文将就生物素化荧光素酶的克隆、表达以及功能检测进行具体讨论。     

Effect of ligand binding and conformational changes in proteins on oxygen quenching and fluorescence depolarization of tryptophan residues

The rotational freedom of tryptophan residues in protein-ligand complexes was studied by measuring steady-state fluorescence anisotropies under conditions of oxygen quenching. There was a decrease in the oxygen bimolecular quenching constant upon complexation of trypsin and alpha-chymotrypsin with proteinaceous trypsin inhibitors, of lysozyme with N-acetylglucosamine (NAG) and di(N-acetyl-D-glucosamine) ((NAG)2) and of hexokinase with glucose. Binding of the bisubstrate analogue N-phosphonacetyl-L-aspartate (PALA) to aspartate transcarbamylase (ATCase) and binding of biotin to avidin resulted in increased oxygen quenching constants. The tryptophan of human serum albumin (HSA) in the F state was more accessible to oxygen quenching than that in the N state. With the exception of ATCase, the presence of subnanosecond motions of the tryptophan residues in all the proteins is suggested by the short apparent correlation times for fluorescence depolarization and by the low apparent anisotropies obtained by extrapolation to a lifetime of zero. Complex formation evidently resulted in more rigid structures in the case of trypsin, alpha-chymotrypsin and lysozyme. The effects of glucose binding on hexokinase were not significant. Binding of biotin to avidin resulted in a shorter correlation time for the tryptophan residues. The N --> F transition in HSA resulted in a more rigid environment for the tryptophan residue. Overall, these changes in the dynamics of the protein matrix and motional freedom of tryptophan residues due to complex formation and subsequent conformational changes are in the same direction as those observed by other techniques, especially hydrogen exchange. Significantly, the effects of complex formation on protein dynamics are variable. Among the limited number of cases we examined, the effects of complex formation were to increase, decrease or leave unchanged the apparent dynamics of the protein matrix.     

Structure-based rational design of streptavidin mutants with pseudo-catalytic activity

Introduction of enzymatic activity into proteins or other types of polymers by rational design is a major objective in the life sciences. To date, relatively low levels of enzymatic activity could be introduced into antibodies by using transition-state analogues of haptens. In the present study, we identify the structural elements that contribute to the observed hydrolytic activity in egg white avidin, which promote the cleavage of active biotin esters (notably biotinyl p-nitrophenyl ester). The latter elements were then incorporated into bacterial streptavidin via genetic engineering. The streptavidin molecule was thus converted from a protector to an enhancer of hydrolysis of biotin esters. The conversion was accomplished by the combined replacement of a "lid-like loop" (L3,4) and a leucine-to-arginine point mutation in streptavidin. Interestingly, neither of these elements play a direct role in the hydrolytic reaction. The latter features were thus shown to be responsible for enhanced substrate hydrolysis. This work indicates that structural and non-catalytic elements of a protein can be modified to promote the induced fit of a substrate for subsequent interaction with either a catalytic residue or water molecules. This approach complements the conventional design of active sites that involves direct modifications of catalytic residues.