Intermolecular interaction of avidin and PEGylated biotin

The equilibrium binding constants and stoichiometries between PEGylated biotins and avidin have been studied for a range of PEGylated biotin molecular weights. These studies show that as the molecular weight of PEG (polyethylene glycol) increases over the range 588, 3400, and 5000 g/mol, the equilibrium dissociation constants of PEGylated biotins with avidin increase to approximately 10 (-8) M compared with 10 (-15) M for the biotin-avidin complex. The stoichiometries of PEGylated biotins with avidin are 4:1 for 588 and 3400 g/mol PEG and 1:1 for 5000 g/mol PEG. The data demonstrate that the equilibrium binding constant and the stoichiometry of the avidin-biotin-PEG complex system can be adjusted by the length of PEG chains. This approach may be used with PEGylated biotin analogues for pretargeting in drug delivery, such as a biotin-PEGylated enzyme for converting an inactive prodrug into a cytotoxin. When a PEG chain is chosen as an appropriate spacer, the length of the PEG chain must be considered because PEG can block the binding sites on avidin.     

"SMART" drug delivery systems: double-targeted pH-responsive pharmaceutical nanocarriers

To develop targeted pharmaceutical carriers additionally capable of responding to certain local stimuli, such as decreased pH values in tumors or infarcts, targeted long-circulating PEGylated liposomes and PEG-phosphatidylethanolamine (PEG-PE)-based micelles have been prepared with several functions. First, they are capable of targeting a specific cell or organ by attaching the monoclonal antimyosin antibody 2G4 to their surface via pNP-PEG-PE moieties. Second, these liposomes and micelles were additionally modified with biotin or TAT peptide (TATp) moieties attached to the surface of the nanocarrier by using biotin-PE or TATp-PE or TATp-short PEG-PE derivatives. PEG-PE used for liposome surface modification or for micelle preparation was made degradable by inserting the pH-sensitive hydrazone bond between PEG and PE (PEG-Hz-PE). Under normal pH values, biotin and TATp functions on the surface of nanocarriers were "shielded" by long protecting PEG chains (pH-degradable PEG(2000)-PE or PEG(5000)-PE) or by even longer pNP-PEG-PE moieties used to attach antibodies to the nanocarrier (non-pH-degradable PEG(3400)-PE or PEG(5000)-PE). At pH 7.4-8.0, both liposomes and micelles demonstrated high specific binding with 2G4 antibody substrate, myosin, but very limited binding on an avidin column (biotin-containing nanocarriers) or internalization by NIH/3T3 or U-87 cells (TATp-containing nanocarriers). However, upon brief incubation (15-30 min) at lower pH values (pH 5.0-6.0), nanocarriers lost their protective PEG shell because of acidic hydrolysis of PEG-Hz-PE and acquired the ability to become strongly retained on an avidin column (biotin-containing nanocarriers) or effectively internalized by cells via TATp moieties (TATp-containing nanocarriers). We consider this result as the first step in the development of multifunctional stimuli-sensitive pharmaceutical nanocarriers.     

A spin label study of egg white avidin.

Avidin is a tetrametric protein (mass 68,000 daltons) that binds 4 molecules of vitamin biotin (1). The biotin binding sites, 1 per subunit, are grouped in two pairs at opposite ends of the avidin molecule (GREEN, N.M., KONIECZNY, L., TOMS, E.J., and VALENTINE, R.C. (1971) Biochem. J. 125, 781). We have studied the topography of the avidin binding sites with the aid of four spin-labeled analogs of biotin: 4-biotinamido-2,2,6,6-tetramethyl-1-piperidinyloxy (II), 3-biotinamido-2,2,5,5-tetramethyl-1-pyrrolidinyloxy (III), 3-biotinamidomethyl-2,2,5,5-tetramethyl-1-pyrrolidinyloxy (IV), 4-(biotinylglycyl)-amino-2,2,6,6-tetramethyl-1-piperidinyloxy (V). Fluorescence and optical absorption spectroscopy indicated that II to V occupied the same binding sites on avidin as did biotin. The electron spin resonance spectrum of the 4:1 complex between II and avidin contained broad line components characteristic of a highly immobilized spin label. Dipole-dipole interactions between spin labels bound to adjacent sites split each of the three major hyperfine lines into doublets with a separation of 13.8 G. The distance between adjacent bound nitroxide groups was calculated from this splitting to be 16 A. The dissociation of the 4:1 complex between II and avidin was biphasic with approximately half of the labels dissociating at a rate (kdiss equal to 2.51 times 10- minus 4 s- minus 1) that was much faster than the remainder (kdiss equal to 1.22 times 10- minus 5 s- minus 1). The electron spin resonance spectrum of the 2:1 complex between II and avidin clearly showed that, immediately after mixing, the spin labels were distributed in a random fashion among the available binding sites but that they slowly redistributed themselves so that each label bound to a site which was adjacent to an unoccupied site. The final time-independent electron spin resonance spectrum exhibited a splitting 69 G between the low and high field hyperfine lines which is characteristic of a highly immobilized, noninteracting spin label. Spin labels III and IV interacted with avidin in a similar fashion to that described for II with the exception that their dipolar splittings were 11.9 G and 14.2 G, respectively. From these splittings it was estimated that the distance between adjacent avidin-bound nitroxides was 16.7 A for labeled III and 15.7 A for label IV. The electron spin resonance spectrum of label V bound to avidin was characteristic of a noninteracting highly immobilized nitroxide with a maximum splitting of 62 G. The spectrum of V bound to avidin was independent of both time and the amount of bound label. The rate of dissociation of V from a 4:1 complex with avidin was monophasic. A model is proposed in which the recognition site for the heterocyclic ring system of biotin is represented as a cleft located within a hydrophobic depression in the surface of avidin.     

Avidin binding of biotinylated analogues of substance P

We report the bioactivities of three biotinylated analogues of Substance P, [alpha-biotinyl-Lys3]Substance P-(3-11), [alpha-biotinyl-Arg1]Substance P, [epsilon-biotinyl-Lys3]Substance P, as well as the bioactivities of their complexes with avidin on guinea pig ileum. The rate of dissociation of an [alpha-biotinyl-Arg1]Substance P-avidin complex has been determined in the presence of 2-(4'-hydroxyazobenzene) benzoic acid and [3H]biotin. The biphasic dissociation of a 4:4 complex between [alpha-biotinyl-Arg1]Substance P and avidin led us to postulate the existence of two sets of binding sites, with the following rates of dissociation, at 4 degrees C, kappa-1 = 6 x 10(-4) x s-1 and kappa-1 = 1.2 x 10(-5) x s-1. We have confirmed this non-equivalence of the four binding sites of avidin by nuclear magnetic resonance using a spin-echo technique. The [alpha-biotinyl-Arg1]Substance P-avidin may be used for the affinity chromatography of Substance P receptors and the decreased affinity of this complex may be taken as an advantage since it can be displaced under mild conditions, i.e. by biotin-containing buffer.     

Dynamic force measurements of avidin-biotin and streptavdin-biotin interactions using AFM

Using atomic force microscopy (AFM) we performed dynamic force measurements of the adhesive forces in two model systems: avidin-biotin and streptavidin-biotin. In our experiments we used glutaraldehyde for immobilization of (strept)avidin on the tip and biotin on the sample surface. Such interface layers are more rigid than those usually reported in the literature for AFM studies, when (strept)avidin is coupled with biotinylated bovine albumin and biotin with agarose polymers. We determined the dependence of the rupture forces of avidin-biotin and streptavidin-biotin bonds in the range 300-9600 pN/s. The slope of a semilogarithmic plot of this relation changes at about 1700 pN/s. The existence of two different regimes indicates the presence of two activation barriers of these complexes during the dissociation process. The dissociation rates and activation energy barriers, calculated from the Bell model, for the avidin-biotin and streptavidin-biotin interactions are similar to each other for loading rates > 1700 pN/s but they are different from each other for loading rates < 1700 pN/s. In the latter case, the dissociation rates show a higher stability of the avidin-biotin complex than the streptavidin-biotin complex due to a larger outer activation barrier of 0.8 k(B)T. The bond-rupture force is about 20 pN higher for the avidin-biotin pair than for the streptavidin-biotin pair for loading rates < 1700 pN/s. These two experimental observations are in agreement with the known structural differences between the biotin binding pocket of avidin and of streptavidin.     

Polyion complex micelles with protein-modified corona for receptor-mediated delivery of oligonucleotides into cells.

Graft-copolymers, containing poly(ethylene glycol) (PEG) and polyethyleneimine (PEI) chains have been proposed as carriers for delivery of phosphorothioate oligonucleotides (SODNs). Complexes of such copolymers with SODN self-assemble into particles having a core of neutralized PEI and SODN and a corona of PEG. Transferrin molecules are attached to the PEG corona using avidin/biotin construct. For this purpose, biotin moieties are covalently linked to the free ends of the PEG chains in the PEG-g-PEI copolymer. SODNs are reacted with mixtures of biotinylated and biotin-free PEG-g-PEI copolymers of various compositions to adjust the number of the biotin moieties in the complex. Resulting complexes have small size (ca. 40 nm) and do not aggregate in aqueous solutions for at least several days. To attach transferrin, they are supplemented first with avidin and then with biotin-transferrin conjugate. This increases the effective diameter of the particles to ca. 75-103 nm, depending on the composition of the complex. Cellular accumulation and fluorescence microscopy studies characterize the effects of these modifications on interaction of fluorescently labeled SODNs with KBv cell monolayers. The data suggest significant enhancement of SODN association with cells resulting from modification of the complex with transferrin. SODN complimentary to the site 546-565 of human mdr 1-mRNA was used to inhibit expression of the drug efflux transporter, P-glycoprotein (P-gp), in multiple drug resistant (MDR) cancer cells (KBv, MCF-7 ADR). Accumulation of a P-gp specific probe, rhodamine 123, in the cell monolayers is used to characterize the effects on P-gp efflux system following the treatment of the cells with antisense SODN or its complexes. This study suggests that antisense SODN incorporated in the complexes retain the ability to inhibit P-gp efflux system, while complexes of the randomized control SODN are inactive. Therefore, the antisense SODN is released from the complex and interacts with its intracellular target upon interaction of the complexes with the cells. Furthermore, modification of the complexes with transferrin leads to a significant increase of the effects of the antisense SODN on the P-gp efflux system in the cells. Overall, this study suggests that polyion complex micelles with protein-modified corona are promising tools for the delivery of antisense SODN.     

Avidin binding of radiolabeled biotin derivatives

Three N-acyl derivatives of biotinylethylenediamine were prepared: I, biotinylamidoethyl-3-(3-[125I]iodo-4-hydroxyphenyl)propionamide; II, biotinylamidoethyl-[3H]acetamide; and III, biotinylamidoethyl-3-(3,5-[125I]diiodo-4-hydroxyphenyl)propionamid e. Each compound was combined with a large excess of avidin, yielding 1:1 molar complexes. Aside from a small fraction of each complex that dissociated more rapidly, the dissociation half-lives of these complexes were: I, 41 days; II, 4.4 days; and III, 148 days. The iodo- (mono or di) hydroxyphenylpropionyl moieties of I and III, therefore, contribute significantly to the binding strength of these compounds toward avidin. We also formed 4:1 complexes of I, II, and III with avidin (compound in excess), each of which exhibited biphasic dissociation, with initial half-lives of 4, 3.2, and 24 days, respectively. Thus, I or especially III potentially can be used as a sensitive tracer in quantitative studies with avidin.     

Preparation and characterization of active site protected poly(ethylene glycol)–avidin bioconjugates

Avidin was modified with poly(ethylene glycol) in the presence of a biotin binding site protective agent synthesised by imminobiotin conjugation to branched 20 kDa PEG. Avidin was incubated with imminobiotin–PEG and reacted with high amounts of 5, 10 or 20 kDa PEG to modify the protein amino groups. Circular dichroism demonstrated that the extensive PEGylation does not alter the protein conformational structure. The affinity of avidin–PEG conjugates for biotin and biotinylated antibodies depended on the PEG size or the use of a protective agent. Avidin–PEG 10 and 20 kDa prepared in the presence of imminobiotin–PEG maintained 100% of the native affinity for biotin. The 5 kDa PEG derivative and the ones obtained without biotin site protection maintained 79–85% of the native affinity. The affinity for biotinylated antibodies decreased to 35% when the conjugation was performed without imminobiotin–PEG, while the conjugates obtained with high-molecular-weight PEGs in the presence of protective agent displayed high residual affinity. All conjugates possessed negligible antigenicity and immunogenicity. PEGylation greatly prolonged the avidin permanence in the circulation, reduced its disposition in the liver and kidneys and promoted accumulation into solid tumors. PEGylation was found to prevent the protein cell uptake, either by phagocytosis or pinocytosis.     

A novel spectroscopic titration method for determining the dissociation constant and stoichiometry of protein-ligand complex.

We offer a new titration protocol for determining the dissociation constant and binding stoichiometry of protein-ligand complex, detectable by spectroscopic methods. This approach neither is limited to the range of protein or ligand concentrations employed during titration experiment nor relies on precise determinations of the titration "endpoint," i.e., the maximal signal changes upon saturation of protein by ligand (or vice versa). In this procedure, a fixed concentration of protein (or ligand) is titrated by increasing volumes of a stock ligand (or protein) solution, and the changes in the spectroscopic signal are recorded after each addition of the titrant. The signal for interaction between protein and ligand first increases, reaches a maximum value, and then starts decreasing due to dilution effect. The volume of the titrant required to achieve the maximum signal changes is utilized to calculate the dissociation constant and the binding stoichiometry of the protein-ligand complex according to the theoretical relationships developed herein. This procedure has been tested for the interaction of avidin with a chromophoric biotin analogue, 2-(4'-hydroxyazobenzene)benzoic acid by following the absorption signal of their interaction at 500 nm. The widespread applicability of this procedure to protein-ligand complexes detected by other spectroscopic techniques and its advantages over conventional methods are discussed.     

A modular design of low‐background bioassays based on a high‐affinity molecular pair barstar:barnase

High‐affinity molecular pairs provide a convenient and flexible modular base for the design of molecular probes and protein/antigen assays. Specificity and sensitivity performance indicators of a bioassay critically depend on the dissociation constant (K_D) of the molecular pair, with avidin:biotin being the state‐of‐the‐art molecular pair (K_D ～ 1 fM) used almost universally for applications in the fields of nanotechnology and proteomics. In this paper, we present an alternative high‐affinity protein pair, barstar:barnase (K_D ～ 10 fM), which addresses several shortfalls of the avidin:biotin system, including non‐negligible background due to the non‐specific binding. A quantitative assessment of the non?specific binding carried out using a model assay revealed inherent irreproducibility of the [strept]avidin:biotin‐based assays, attributed to the avidin binding to solid phases, endogenous biotin molecules and serum proteins. On the other hand, the model assays assembled via a barstar:barnase protein linker proved to be immune to such non‐specific binding, showing good prospects for high‐sensitivity rare biomolecular event nanoproteomic assays.     

A fluorescence polarization assay to quantify biotin and biotin-binding proteins in whole plant extracts using Alexa-Fluor 594 biocytin

A high-throughput fluorescence polarization assay has been developed for the detection of biotin and biotin-binding proteins in whole leaf extracts. Various groups are investigating the insecticidal properties of avidin and other biotin-binding proteins expressed in leaves of transgenic plants. The methods commonly used to quantify biotin and avidin in leaf extracts are enzyme-linked immunosorbent assay (ELISA) and Western blotting. Here we describe a homogeneous fluorescence polarization (FP) method that quantifies transgenic avidin in whole leaf extract by the simple addition of the fluorescent avidin ligand Alexa-Fluor 594 biocytin (AFB). The FP assay exploits the fact that AFB excites and emits in regions of the spectrum that are relatively free of background fluorescence in leaf extract. Transgenic leaf avidin can be quantified within 1-2 h by the FP method, in comparison with 1-2 days for ELISA and Western blotting. The FP method can also measure the amount of biotin in control leaves, not expressing avidin. Functional avidin levels of 1.54 μM (26.1 μg/g leaf tissue) were detected in tobacco leaves expressing vacuole-targeted avidin. Control leaves had biotin levels of around 0.74 μM (∼0.18 μg/g leaf tissue). Reagent costs are minimal: typically AFB is used at concentrations of 1-10 nM, avidin is used at 1-100 nM, and sample volumes are 20 μL in 384-well microplates.     

Avidin-biotin interactions at vesicle surfaces: adsorption and binding, cross-bridge formation, and lateral interactions.

Densely packed domains of membrane proteins are important structures in cellular processes that involve ligand-receptor binding, receptor-mediated adhesion, and macromolecule aggregation. We have used the biotin-avidin interaction at lipid vesicle surfaces to mimic these processes, including the influence of a surface grafted polymer, polyethyleneglycol (PEG). Single vesicles were manipulated by micropipette in solutions of fluorescently labeled avidin to measure the rate and give an estimate of the amount of avidin binding to a biotinylated vesicle as a function of surface biotin concentration and surface-grafted PEG as PEG-lipid. The rate of avidin adsorption was found to be four times less with 2 mol% PEG750 than for the unmodified surface, and 10 mol% PEG completely inhibited binding of avidin to biotin for a 2-min incubation. Using two micropipettes, an avidin-coated vesicle was presented to a biotinylated vesicle. In this vesicle-vesicle adhesion test, the accumulation of avidin in the contact zone was observed, again by using fluorescent avidin. More importantly, by controlling the vesicle membrane tension, this adhesion test provided a direct measure of the spreading pressure of the biotin-avidin-biotin cross-bridges confined in the contact zone. Assuming ideality, this spreading pressure gives the concentration of avidin cross-bridges in the contact zone. The rate of cross-bridge accumulation was consistent with the diffusion of the lipid-linked "receptors" into the contact zone. Once adherent, the membranes failed in tension before they could be peeled apart. PEG750 did not influence the mechanical equilibrium because it was not compressed in the contact zone, but it did perform an important function by eliminating all nonspecific adhesion. This vesicle-vesicle adhesion experiment, with a lower tension limit of 0.01 dyn/cm, now provides a new and useful method with which to measure the spreading pressures and therefore colligative properties of a range of membrane-bound macromolecules.     

Molecular modeling of p-chlorophenoxyacetic acid binding to the CLC-0 channel

Molecular simulation techniques were applied to predict the interaction of the CLC-0 Cl(-) channel and the channel-blocking molecule p-chlorophenoxyacetic acid (CPA). A three-dimensional model of the CLC-0 channel was constructed on the basis of the homology with the bacterial Cl(-) channel StCLC, the structure of which has been solved by X-ray crystallography. Docking of the CPA molecule was obtained by using a geometric recognition algorithm, yielding 5000 possible conformations. By restraining the simulation to those conformations in which CPA is near the intracellular mouth of the channel, the CPA-protein complex models were reduced to three sets of conformations, which are interconvertible within 2 ns when molecular dynamics is applied to the system. Point mutations of CLC-0 at three different positions predicted to interact with CPA in these configurations did, however, not greatly alter CPA inhibition, suggesting a deeper final binding location. In the model, binding of CPA to a more internal position in the ionic pathway was obtained by applying a constant force vector to CPA, pushing it toward the center of the channel. This technique allowed us to outline the possible intrachannel pathway of CPA and to describe qualitatively the binding sites and energy barriers of this pathway. The consistency of the obtained models and the experimental data indicates that the CLC-0-CPA complex model is reasonable and can be used in further biological studies, such as rational design of blocking agents of and mutagenesis of CLC Cl(-) channels.     

Investigating the binding behaviour of two avidin‐based testosterone binders using molecular recognition force spectroscopy

Molecular recognition force spectroscopy, a biosensing atomic force microscopy technique allows to characterise the dissociation of ligand–receptor complexes at the molecular level. Here, we used molecular recognition force spectroscopy to study the binding capability of recently developed testosterone binders. The two avidin‐based proteins called sbAvd‐1 and sbAvd‐2 are expected to bind both testosterone and biotin but differ in their binding behaviour towards these ligands. To explore the ligand binding and dissociation energy landscape of these proteins, we tethered biotin or testosterone to the atomic force microscopy probe while the testosterone‐binding protein was immobilized on the surface. Repeated formation and rupture of the ligand–receptor complex at different pulling velocities allowed determination of the loading rate dependence of the complex‐rupturing force. In this way, we obtained the molecular dissociation rate (k_off) and energy landscape distances (x_β) of the four possible complexes: sbAvd‐1‐biotin, sbAvd‐1‐testosterone, sbAvd‐2‐biotin and sbAvd‐2‐testosterone. It was found that the kinetic off‐rates for both proteins and both ligands are similar. In contrast, the x_β values, as well as the probability of complex formations, varied considerably. In addition, competitive binding experiments with biotin and testosterone in solution differ significantly for the two testosterone‐binding proteins, implying a decreased cross‐reactivity of sbAvd‐2. Unravelling the binding behaviour of the investigated testosterone‐binding proteins is expected to improve their usability for possible sensing applications. Copyright © 2014 John Wiley & Sons, Ltd.     

Abeta(1-40) peptide radiopharmaceuticals for brain amyloid imaging: (111)In chelation, conjugation to poly(ethylene glycol)-biotin linkers, and autoradiography with Alzheimer's disease brain sections

The amyloid plaques of Alzheimer's disease (AD) are formed by the neuropeptide Abeta(1)(-)(42/43), and carboxyl terminal truncated forms of this neuropeptide, designated Abeta(1)(-)(40), bind to amyloid plaques of AD autopsy tissue sections. Therefore, Abeta(1)(-)(40) is a potential peptide radiopharmaceutical that could be used for imaging brain amyloid in living subjects with AD, should this neuropeptide be made transportable through the blood-brain barrier (BBB). To accomplish this, the neuropeptide must be modified to enable (i) attachment to a BBB drug targeting system and (ii) labeling with a radionuclide, e.g., 111-indium, suitable for brain imaging by external detection modalities such as single photon emission computed tomography (SPECT). The present studies describe the synthesis of an Abeta(1)(-)(40) analogue that contains a biotin at the amino terminus and a diethylenetriaminepentaacetic acid (DTPA) moiety conjugated to one of the internal lysine residues. The DTPA-[N-biotin]-Abeta(1)(-)(40) was purified by gel filtration fast-protein liquid chromatography (FPLC) using two Superose 12HR columns in series, and the structure of the purified peptide was confirmed by matrix-assisted laser desorption ionization (MALDI) mass spectrometry. The binding of the [(111)In]DTPA-[N-biotin]-Abeta(1)(-)(40) to amyloid plaques of AD autopsy tissue sections was demonstrated by film and emulsion autoradiography. A poly(ethylene glycol) (PEG) linker of 3400 Da molecular mass, designated PEG(3400), was inserted between the Abeta(1)(-)(40) and the biotin moiety, but this modification diminishes binding of Abeta(1)(-)(40) to the AD amyloid plaques. In summary, these studies describe a novel formulation of biotinylated Abeta(1)(-)(40) that allows radiolabeling with 111-indium. The peptide radiopharmaceutical may be conjugated to an avidin-based BBB drug targeting system to enable transport through the BBB and imaging of brain amyloid in vivo.     

Fluorometric assay for quantitation of biotin covalently attached to proteins and nucleic acids

As a component of the (strept)avidin affinity system, biotin is often covalently linked to proteins or nucleic acids. We describe here a microplate-based high-throughput fluorometric assay for biotin linked to either proteins or nucleic acids based on fluorescence resonance energy transfer (FRET). This assay utilizes a complex of Alexa Fluoro 488 dye-labeled avidin with a quencher dye, 2-(4'-hydroxyazobenzene) benzoic acid (HABA), occupying the biotin binding sites of the avidin. In the absence of biotin, HABA quenches the fluorescence emission of the Alexa Fluor 488 dyes via FRET HABA is displaced when biotin binds to the Alexa Fluor 488 dye-labeled avidin, resulting in decreased FRET efficiency. This mechanism results in an increase in fluorescence intensity directly related to the amount of biotin present in the sample. The assay is able to detect as little as 4 pmol biotin in a 0.1 mL volume within 15 min of adding sample to the reagent, with a Z-factor > 0.9.     

Dissociative binding of alpha- and beta-sulphoxides of biotinylamidoethyl-3-(4-hydroxy-3-[125I]iodophenyl)propionamide to avidin.

Previously we reported the dissociative binding of biotinylamidoethyl-3-(4-hydroxy-3-[125I]iodophenyl)propionamide to avidin [Garlick & Giese (1988) J. Biol. Chem. 263, 210-215]. In the present paper we report the corresponding binding of the alpha- and beta-sulphoxides of this parent compound to avidin. The 1:1 complex (obtained with avidin in excess) of the alpha-sulphoxide derivative with avidin has a dissociation half-life (t1/2) of 25 days, only 1.6 times as fast as the parent compound (t1/2 41 days). However, the corresponding beta-sulphoxide dissociates 446 times faster (t1/2 0.092 day) than the parent compound, this apparently being due to a steric effect. The alpha-sulphoxide is attractive as a tracer reagent to facilitate studies and applications of the avidin-biotin system.     

Biotin reagents for antibody pretargeting. 5. Additional studies of biotin conjugate design to provide biotinidase stability.

An investigation was conducted in which the stabilities of four structurally different biotin derivatives were assessed with regard to biotinamide bond hydrolysis by the enzyme biotinidase. The biotin derivatives studied contained an extra methylene in the valeric acid chain of biotin (i.e., homobiotin), or contained conjugated amino acids having hydroxymethylene, carboxylate, or acetate functionalities on a methylene alpha to the biotinamide bond. The biotinidase hydrolysis assay was conducted on biotin derivatives that were radioiodinated at high specific activity, and then subjected to diluted human serum at 37 degrees C for 2 h. After incubation, assessment of biotinamide bond hydrolysis by biotinidase was readily achieved by measuring the percentage of radioactivity that did not bind with avidin. As controls, an unsubstituted biotin derivative which is rapidly cleaved by biotinidase and an N-methyl-substituted biotin derivative which is stable to biotinidase cleavage were included in the study. The results indicate that increasing the distance from the biotin ring structure to the biotinamide bond by one methylene only decreases the rate of biotinidase cleavage, but does not block it. The data obtained also indicate that placing a hydroxymethylene, carboxylate, or acetate alpha to the biotinamide bond is effective in blocking the biotinamide hydrolysis reaction. These data, in combination with data previously obtained, which indicate that biotin derivatives containing hydroxymethylene or carboxylate moieties retain the slow dissociation rate of biotin from avidin and streptavidin [Wilbur, D. S., et al. (2000) Bioconjugate Chem. 11, 569-583], strongly support incorporation of these structural features into biotin derivatives being used for in vivo targeting applications.     

Comparison of avidin and biotin levels in eggs from turkey hens with high and low hatchability records

Levels of biotin and avidin were assayed in eggs from Small White turkey hens having 12-15 week average hatchability of fertile egg records (HF) of 13 and 99%. The median level and concentration of avidin was higher in eggs of the 13% HF (2.72 mg and 42.5 micrograms/ml, respectively) as compared with the 99% HF (1.39 mg and 23.8 micrograms/ml, respectively). Calculations for total biotin to avidin binding in the eggs revealed that all eggs in the 13% HF and residual free avidin levels after total biotin was complexed to avidin. This complex formation is expected to have limited the availability of biotin for embryonic development.     

Extension of the single amino acid chelate concept (SAAC) to bifunctional biotin analogues for complexation of the M(CO)3(+1) Core (M = Tc and Re): syntheses, characterization, biotinidase stability, and avidin binding

Biotin and avidin form one of the most stable complexes known (K(D) = 10(-15) M(-1)) making this pairing attractive for a variety of biomedical applications including targeted radiotherapy. In this application, one of the pair is attached to a targeting molecule, while the other is subsequently used to deliver a radionuclide for imaging and/or therapeutic applications. Recently, we reported a new single amino acid chelate (SAAC) capable of forming stable complexes with Tc(CO)3 or Re(CO)3 cores. We describe here the application of SAAC analogues for the development of a series of novel radiolabeled biotin derivatives capable of forming robust complexes with both Tc and Re. Compounds were prepared through varying modification of the free carboxylic acid group of biotin. Each 99mTc complex of SAAC-biotin was studied for their ability to bind avidin, susceptibility to biotinidase, and specificity for avidin in an in vivo avidin-containing tumor model. The radiochemical stability of the 99mTc(CO)3 complexes was also investigated by challenging each 99mTc-complex with large molar excesses of cysteine and histidine at elevated temperature. All compounds were radiochemically stable for greater than 24 h at elevated temperature in the presence of histidine and cysteine. Both [99mTc(CO)3(L6)]+1 [TcL6; L6 = biotinylamidopropyl-N,N-(dipicolyl)amine] and [99mTc(CO)3(L12a)]+1 (TcL12; L12 = N,N-(dipicolyl)biotinamido-Boc-lysine; TcL12a; L12a = N,N-(dipicolyl)biotinamide-lysine) readily bound to avidin whereas [99mTc(CO)3(L9)]+1 [TcL9; L9 = N,N-(dipicolyl)biotinamine] demonstrated minimal specific binding. TcL6 and TcL9 were resistant to biotinidase cleavage, while TcL12a, which contains a lysine linkage, was rapidly cleaved. The highest uptake in an in vivo avidin tumor model was exhibited by TcL6, followed by TcL9 and TcL12a, respectively. This is likely the result of both intact binding to avidin and resistance to circulating biotinidase. Ligand L6 is the first SAAC analogue of biotin to demonstrate potential as a radiolabeled targeting vector of biotin capable of forming robust radiochemical complexes with both 99mTc and rhenium radionuclides. Computational simulations were performed to assess biotin-derivative accommodation within the binding site of the avidin. These calculations predict that deformation of the surface domain of the binding pocket can occur to accommodate the transition metal-biotin derivatives with negligible changes to the inner-beta-barrel, the region most responsible for binding and retaining biotin and its derivatives. The biological activity and biodistribution of the technetium complexes TcL6, TcL9, and TcL12a were examined in an avidin tumor model. In the avidin bead tumor localization model, TcL6 demonstrated the most favorable localization with a 7:1 ratio of avidin bead implanted muscle versus normal muscle, while TcL9 exhibited a 2:1 ratio. However, TcL9 displayed no specificity for avidin.