Affinity enhancement bivalent morpholino for pretargeting: initial evidence by surface plasmon resonance

Pretargeting with bivalent effectors capable of bridging antitumor antibodies has been reported to provide superior results by affinity enhancement. Morpholinos (MORFs) and other DNA analogues used for pretargeting are ideally suited as bivalent effectors since they are easily synthesized and the distance between binding regions, likely to be a determinant of binding, may be adjusted simply by lengthening the chain. The goal of this investigation was to synthesize a bivalent MORF and to determine by surface plasmon resonance (SPR) whether the bivalent MORF exhibited bimolecular binding and whether the MORFs showed improved in vitro hybridization affinity in its bivalent form compared to its monovalent form. An 18 mer amino-derivitized MORF was made bivalent by dimerizing with disuccinimidyl suberate (DSS) in 1-methyl-2-pyrrolidinone (NMP) with N,N-diisopropylethylamine (DIEA) followed by purification by ion exchange chromatography. The in vitro hybridization affinity of bivalent compared to monovalent MORF was then measured by SPR. For these measurements, the complementary biotinylated cDNA was immobilized at coating densities that provided an average spacing of 20-100 angstroms and used to investigate the influence of this spacing on binding of the bivalent MORF with its binding regions separated by 25 A. The yield of bivalent MORF was as high as 45%, and the structure was confirmed by MALDI-TOF mass spectroscopy. When the sensograms obtained by SPR were analyzed using different binding models, the evidence was consistent with bimolecular binding of the bivalent MORF. The dissociation rate constant of the bivalent compared to monovalent MORF was more than 10-fold lower at 2.14 compared to 0.27 x 10(-5) (1/s) (p < 0.05), and since the association rate constants were similar at 8.53 and 5.64 x 10(5) (1/M.s) (p = 0.08), the equilibrium constant for hybridization to the immobilized cDNA of the bivalent compared to the monovalent MORF was almost 20-fold higher at 3.99 compared to 0.21 x 10(10) (1/M) (p < 0.05). In addition, qualitative evidence for bivalent binding of the bivalent MORF was apparent in the lower concentrations necessary to saturate the cDNA. Finally, the stoichiometry interpretation of the binding data provided estimates of the fraction of bivalent MORF binding bimolecularly. Under one set of conditions, this value was 20%. In conclusion, a bivalent MORF was easily synthesized by dimerization of a monovalent MORF. A lower dissociation rate constant and higher equilibrium constant was measured by SPR for the bivalent compared to monovalent MORF in their binding to an immobilized cDNA. These results show that bimolecular binding was occurring in the case of the bivalent MORF and suggest that bivalency may be superior to monovalency in MORF pretargeting applications.     

An improved method for covalently conjugating morpholino oligomers to antitumor antibodies

Whether for conventional pretargeting, amplification pretargeting, or affinity enhancement pretargeting, it will be necessary to conjugate an antitumor antibody as the first injectate. This laboratory is investigating phosphorodiamidate morpholinos (MORFs) for pretargeting, and accordingly we are examining methods of attaching MORFs to antitumor antibodies that provide at least one group per molecule (gpm) without adversely influencing antibody properties. The aim of this investigation was to evaluate the commercial Hydralink for the conjugation of the anti-CEA MN14 antibody with an 18 mer amine-derivatized MORF. The conjugation was approached in both directions by first reacting MN14 with the NHS derivatives of 4-hydrozinonicotinate acetone hydrazone (SANH) or 4-formylbenzoate (SFB) and then combining with MORF that was previously reacted with SFB or SANH to yield MN14(SANH)-MORF and MN14(SFB)-MORF respectively. The storage stability, immunoreactive fraction, and the biodistribution in normal mice were compared for both conjugates. Thereafter, MN14(SANH)-MORF was used in a pretargeting study in tumored nude mice, and the results were compared to that obtained historically with MN14-MORF prepared by carbodiimide (EDC) coupling. Both new methods of conjugation provided between 1 and 2 gpm compared to 0.2 achieved previously by EDC. Furthermore, by repeat SE HPLC with and without CEA, both showed an unimpaired immunoreactive fraction. MN14(SANH)-MORF tolerated long-term storage best. More importantly, when labeled by hybridization with 99mTc-labeled complementary MORF (99mTc-cMORF), the biodistribution of MN14(SANH)-MORF was more favorable than that of MN14(SFB)-MORF in normal mice with lower liver (5.7 vs 9.4 %ID/g at 18 h) and spleen (3.5 vs 8.4 %ID/g) accumulations and higher blood levels (4.8 vs 3.4 %ID/g). Accordingly, only MN14(SANH)-MORF was used in a pretargeting study in tumored mice. When targeted with 99mTc-cMORF and at 2 days postinjection of antibody-MORF, the results obtained with 6 microg of antibody prepared in this way were essentially identical to that obtained previously with 30 microg of antibody prepared via EDC. Hydralink was used successfully to conjugate MORF to MN14 at higher gpm than that achieved earlier and without an obvious compromise of properties. Using MN14(SANH)-MORF, the influence of the higher gpm on pretargeting permitted lowering the dosages of MN14 administered and may permit administering higher levels of radioactivity in connection with therapy.     

Cytosine residues influence kidney accumulations of 99mTc-labeled morpholino oligomers

Watson-Crick pairing between complementary oligomers is proving to be an effective means for rapidly directing radioisotopes specifically to the exterior surface of cancer cells in vivo. In such pretargeting applications, it is highly desirable that the excess of isotopically labeled oligomers, which do not bind to the cancer cells, be rapidly cleared from the body. In this context, understanding the influence of chain length and base sequence of the radiolabeled oligomers is critical. We had earlier determined that the kidneys are the principal targets of short-chain radiolabeled morpholino oligomers (MORFs). To explain these observations, MORFs consisting of uniform cytosines (Cs), uniform thymines (Ts), uniform adenines (As), and uniform AAG repeat were labeled with technetium-99m (99mTc) and studied in normal mice. In a limited investigation of the influence of oligomer backbone, a 20-mer MORF (MORF20) with a base sequence rich in Cs was compared with a phosphoromonothioate DNA (S-DNA20) of the same sequence. The in vivo behavior of the labeled MORFs was nearly identical in all organs, with the exception of kidneys. The kidney accumulations were about 25- to 80-fold higher for the uniform Cs relative to the other three uniform MORFs at 3 hours. The S-DNA20 rich in Cs showed only modest kidney accumulations compared with the equivalent MORF20, presumably because of preferential clearance of the S-DNA20 through the liver. Urine analysis showed no evidence of intact labeled S-DNA20 in contrast to fully intact labeled MORF20. We conclude that the high kidney levels observed by us previously for MORFs are most likely due largely to the C residues in the base sequence. In the case of S-DNAs, this phenomenon is partly disguised by the increased hepatic excretion and degradation. These results show that the base sequences of MORFs, and probably other oligomers as well, are an important determinant of biodistribution.     

A comparison of in vitro and in vivo stability in mice of two morpholino duplexes differing in chain length

The stability of hybridized duplexes is an important criterion for any radiopharmaceutical application of DNAs or their analogues such as phosphorodiamidate morpholinos (MORFs). OBJECTIVE: The stabilities in vitro and in mice of the duplex between MORF and its complement (cMORF) were investigated for two different chain lengths, a 15-mer MORF compared to the identical MORF but elongated to a 25-mer. METHODS: The hybridization characteristics of the 15-mer MORF with its complementary 15-mer and that of the 25-mer with its complementary 25-mer MORF were measured using surface plasmon resonance (SPR) analysis. For radiolabeling with (99m)Tc, the 15- and 25-mer MORF, both with a primary amine via a 10-member linker on the 3' equivalent end, were conjugated with NHS-MAG(3). The 15- and 25-mer cMORFs were conjugated via their amines to carbodiimidazole treated poly(methyl vinyl ether-alt-maleic acid) (PA) such that about 50 cMORFs were attached to each polymer molecule in both cases (estimated MWs about 300 and 450 kDa, respectively). After hybridization in vitro, both the PA-cMORF15-(99m)Tc-MORF15 and PA-cMORF25-(99m)Tc-MORF25 homoduplexes were evaluated by size exclusion HPLC in saline, after incubation in 37 degrees C serum and in urine obtained 30 min post IV administration to normal mice. Biodistributions were obtained up to 18 h post administration. RESULTS: By SPR, the affinity constants for the homoduplexes were both about 10(9) M(-)(1) with the 25/25 only about 25% higher than the 15/15. However, the affinity constants for the 15/25 and 25/15 heteroduplexes showed a surprisingly 13-fold difference. By HPLC analysis, all duplexes were stable in saline; however, analysis of serum incubates and urine containing PA-cMORF15-(99m)Tc-MORF15 showed an immediate and pronounced low molecular weight peak that was identified by a shift assay to be (99m)Tc-MORF15. The comparable peak in both fluids was much less pronounced in the case of PA-cMORF25-(99m)Tc-MORF25. Whole body radioactivity levels also fell much more rapidly in mice receiving the 15-mer conjugate (65 vs 30% eliminated at 18 h) and biodistribution results showed higher kidney levels for the 15-mer conjugate. Results with the PA-cMORF25-(99m)Tc-MORF15 heteroduplex were more similar to that obtained with the 15-mer homoduplex than the 25-mer homoduplex. CONCLUSION: Despite what is reported to be high hybridization affinities, both the homoduplex and heteroduplexes prepared with (99m)Tc-MORF15 were found to be unstable in serum and in vivo toward dissociation to free (99m)Tc-MORF15. By contrast, homoduplex prepared with (99m)Tc-MORF25 showed higher stability. These differences in hybridization stability may be important considerations in radiopharmaceutical design.     

Development of a Model Protein Interaction Pair as a Benchmarking Tool for the Quantitative Analysis of 2-Site Protein-Protein Interactions

A significant challenge in the molecular interaction field is to accurately determine the stoichiometry and stepwise binding affinity constants for macromolecules having >1 binding site. The mission of the Molecular Interactions Research Group (MIRG) of the Association of Biomolecular Resource Facilities (ABRF) is to show how biophysical technologies are used to quantitatively characterize molecular interactions, and to educate the ABRF members and scientific community on the utility and limitations of core technologies [such as biosensor, microcalorimetry, or analytic ultracentrifugation (AUC)]. In the present work, the MIRG has developed a robust model protein interaction pair consisting of a bivalent variant of the Bacillus amyloliquefaciens extracellular RNase barnase and a variant of its natural monovalent intracellular inhibitor protein barstar. It is demonstrated that this system can serve as a benchmarking tool for the quantitative analysis of 2-site protein-protein interactions. The protein interaction pair enables determination of precise binding constants for the barstar protein binding to 2 distinct sites on the bivalent barnase binding partner (termed binase), where the 2 binding sites were engineered to possess affinities that differed by 2 orders of magnitude. Multiple MIRG laboratories characterized the interaction using isothermal titration calorimetry (ITC), AUC, and surface plasmon resonance (SPR) methods to evaluate the feasibility of the system as a benchmarking model. Although general agreement was seen for the binding constants measured using solution-based ITC and AUC approaches, weaker affinity was seen for surface-based method SPR, with protein immobilization likely affecting affinity. An analysis of the results from multiple MIRG laboratories suggests that the bivalent barnase-barstar system is a suitable model for benchmarking new approaches for the quantitative characterization of complex biomolecular interactions.     

Kinetic analysis of the binding of monomeric and dimeric ephrins to Eph receptors: correlation to function in a growth cone collapse assay

Eph receptors and ephrins play important roles in regulating cell migration and positioning during both normal and oncogenic tissue development. Using a surface plasma resonance (SPR) biosensor, we examined the binding kinetics of representative monomeric and dimeric ephrins to their corresponding Eph receptors and correlated the apparent binding affinity with their functional activity in a neuronal growth cone collapse assay. Our results indicate that the Eph receptor binding of dimeric ephrins, formed through fusion with disulfide-linked Fc fragments, is best described using a bivalent analyte model as a two-step process involving an initial monovalent 2:1 binding followed by a second bivalent 2:2 binding. The bivalent binding dramatically decreases the apparent dissociation rate constants with little effect on the initial association rate constants, resulting in a 30- to 6000-fold decrease in apparent equilibrium dissociation constants for the binding of dimeric ephrins to Eph receptors relative to their monomeric counterparts. Interestingly, the change was more prominent in the A-class ephrin/Eph interactions than in the B-class of ephrins to Eph receptors. The increase in apparent binding affinities correlated well with increased activation of Eph receptors and the resulting growth cone collapse. Our kinetic analysis and correlation of binding affinity with function helped us better understand the interactions between ephrins and Eph receptors and should be useful in the design of inhibitors that interfere with the interactions.     

Direct measurement of equilibrium constants for high-affinity hemoglobins

The biological functions of heme proteins are linked to their rate and affinity constants for ligand binding. Kinetic experiments are commonly used to measure equilibrium constants for traditional hemoglobins comprised of pentacoordinate ligand binding sites and simple bimolecular reaction schemes. However, kinetic methods do not always yield reliable equilibrium constants with more complex hemoglobins for which reaction mechanisms are not clearly understood. Furthermore, even where reaction mechanisms are clearly understood, it is very difficult to directly measure equilibrium constants for oxygen and carbon monoxide binding to high-affinity (K(D) < 1 micro M) hemoglobins. This work presents a method for direct measurement of equilibrium constants for high-affinity hemoglobins that utilizes a competition for ligands between the "target" protein and an array of "scavenger" hemoglobins with known affinities. This method is described for oxygen and carbon monoxide binding to two hexacoordinate hemoglobins: rice nonsymbiotic hemoglobin and Synechocystis hemoglobin. Our results demonstrate that although these proteins have different mechanisms for ligand binding, their affinities for oxygen and carbon monoxide are similar. Their large affinity constants for oxygen, 285 and approximately 100 micro M(-1) respectively, indicate that they are not capable of facilitating oxygen transport.     

The binding of monoclonal antibodies to cell-surface molecules. A quantitative analysis with immunoglobulin G against two alloantigenic determinants of the human transplantation antigen HLA-A2.

Monoclonal IgG1 (immunoglobulin G1) PA2.1 and MA2.1 antibodies recognize polymorphic sites of the human transplantation antigen HLA-A2. They are distinguishable because MA2.1 binds HLA-A2 and HLA-B17, whereas PA2.1 binds HLA-A2 and HLA-A28. The affinities of PA2.1-Fab for HLA-A2, three HLA-A2 variants and HLA-A28 are similar and relatively low (1.9 X 10(7) M-1). The affinities of MA2.1-Fab for HLA-A2, three HLA-A2 variants and HLA-B17 are similar and high (1.2 X 10(9) M-1). The difference in affinity is due to the rates of dissociation, which give half-times of dissociation of 290 min for MA2.1-Fab and 4 min for PA2.1-Fab. For both Fab, equilibrium measurements and kinetic determinations gave consistent estimates for affinity. When PA2.1-F(ab)2 or IgG is incubated with cells it reaches equilibrium within 3 h, with most molecules bound bivalently to the cell. Under similar conditions, MA2.1-F(ab)2 does not reach equilibrium and a significant proportion of molecules bound with one and two sites are found. For the lower-affinity antibody (PA2.1), estimates of the binding constants for one- and two-site interactions could be made. By simple Scatchard analysis the avidity of F(ab)2 or IgG is 1.3 X 10(9) M-1, giving an enhancement factor of 68 between bivalent and univalent binding. This is a measure of the equilibrium constant for the interchange between bivalent and univalent binding. Analysis of the results with more realistic models indicates that the actual value is larger (10(3)-10(4) M-1) than 68 M-1. The avidities of F(ab)2 and IgG for HLA-A2 are identical, showing the Fc does not interfere with bivalent binding to cells.     

Bivalent molecular probes for dopamine D2-like receptors

Merging two arylamidoalkyl substituted phenylpiperazines as prototypical recognition elements for dopamine D(2)-like receptors by oligoethylene glycol linkers led to a series of bivalent ligands. These dimers were investigated in comparison to their monomeric analogues for their dopamine D(2long), D(2short), D(3) and D(4) receptor binding. Radioligand binding experiments revealed strong bivalent effects for some para-substituted benzamide derivatives. For the D(3) subtype, the target compounds 32, 34 and 36 showed an up to 70-fold increase of affinity and a substantial enhancement of subtype selectivity when compared to the monovalent analogue 24. Analysis of the binding curves displayed Hill slopes very close to one indicating that the bivalent ligands displace 1equiv of radioligand. Obviously, the two pharmacophores occupy an orthosteric and an allosteric binding site rather than adopting a receptor-bridging binding mode.     

High-resolution and high-throughput protocols for measuring drug/human serum albumin interactions using BIACORE

Characterizing how chemical compounds bind to human serum albumin (HSA) is essential in evaluating drug candidates. Using warfarin as a test system, we validate the application of BIACORE SPR biosensors to reliably determine binding constants for drug/HSA interactions. The binding responses for warfarin over HSA surfaces were extremely reproducible even though warfarin is small compared to the size of the immobilized protein. At high concentrations, warfarin bound at more than one site on HSA, which is consistent with its known binding properties. The affinity we determined for the high-affinity site (K(25 degrees C)(d) = 3.7 +/- 1.2 microM), as well as the dissociation rate constant (k(25 degrees C)(d) = 1.2 s(-1)), are also consistent with binding constants determined previously. These results validate the biosensor technology and illustrate how BIACORE can be used to study drug/HSA interactions in a high-resolution mode. Using a set of 10 test compounds, we present a protocol for determining equilibrium dissociation constants for HSA in a high-throughput mode. Our method involves working at low compound concentrations and fitting the equilibrium data for all compounds simultaneously. We show that the % bound values determined by SPR correlate with the values determined by solution-based methods. The ability to examine directly the binding of small molecules (130-800 Da), coupled with minimal sample requirements and automated instrumentation, makes BIACORE technology applicable for evaluating drug/HSA interactions.     

The interaction of muscle glycogen phosphorylase b with glycogen

Interaction of muscle glycogen phosphorylase b (EC 2.4.1.1) with glycogen was studied by sedimentation, stopped-flow and temperature-jump methods. The equilibrium enzyme concentration was determined by sedimentation in an analytical ultracentrifuge equipped with absorption optics and a photoelectric scanning system. The maximum adsorption capacity of pig liver glycogen is 3.64 mumol dimeric glycogen phosphorylase b per g glycogen, which corresponds to 20 dimeric enzyme molecules per average glycogen molecule of Mr 5.5 X 10(6). Microscopic dissociation constants were determined for the enzyme-glycogen complex within the temperature range from 12.7 to 30.0 degrees C. Enzyme-glycogen complexing is accompanied by increasing light scattering and its increment depends linearly on the concentration of the binding sites on a glycogen particle that are occupied by the enzyme. Complex formation and relaxation kinetics are in accordance with the proposed bimolecular reaction scheme. The monomolecular dissociation rate constant of the complex increases as the temperature increases from 12.7 to 30.0 degrees C, whereas the bimolecular rate constant changes slightly and is about 10(8) M-1 X S-1. These data point to the possibility of diffusional control of the complex formation.     

Molecular recognition of taxol by microtubules. Kinetics and thermodynamics of binding of fluorescent taxol derivatives to an exposed site

We have determined the kinetic scheme and the reaction rates of binding to microtubules of two fluorescent taxoids, 7-O-[N-(4'-fluoresceincarbonyl)-l-alanyl]Taxol (Flutax-1) and 7-O-[N-(2,7-difluoro-4'-fluoresceincarbonyl)-l-alanyl]Taxol (Flutax-2). Flutax-1 and Flutax-2 bind to microtubules with high affinity (K(a) approximately 10(7) m(-1), 37 degrees C). The binding mechanism consists of a fast bimolecular reaction followed by at least two monomolecular rearrangements, which were characterized with stopped-flow techniques. The kinetic constants of the bimolecular reaction were 6.10 +/- 0.22 x 10(5) m(-1) s(-1) and 13.8 +/- 1.8 x 10(5) m(-1) s(-1) at 37 degrees C, respectively. A second slow binding step has been measured employing the change of fluorescence anisotropy of the probe. The reversal of this reaction is the rate-limiting step of dissociation. A third step has been detected using small angle x-ray scattering and involves a 2-nm increase in the diameter of microtubules. It is suggested that the first step entails the binding of the Taxol moiety and the second a relative immobilization of the fluorescent probe. The equilibrium and some kinetic measurements required the use of stabilized cross-linked microtubules, which preserved taxoid binding. The results indicate that the Taxol binding site is directly accessible, in contrast with its location at lumen in the current model of microtubules. An alternative structural model is considered in which the binding site is located between protofilaments, accessible from the microtubule surface.     

Quantitative interdependence of coeffectors, CcpA and cre in carbon catabolite regulation of Bacillus subtilis

The phosphoproteins HPrSerP and CrhP are the main effectors for CcpA-mediated carbon catabolite regulation (CCR) in Bacillus subtilis. Complexes of CcpA with HPrSerP or CrhP regulate genes by binding to the catabolite responsive elements (cre). We present a quantitative analysis of HPrSerP and CrhP interaction with CcpA by surface plasmon resonance (SPR) revealing small and similar equilibrium constants of 4.8 +/- 0.4 microm for HPrSerP-CcpA and 19.1 +/- 2.5 microm for CrhP-CcpA complex dissociation. Forty millimolar fructose-1,6-bisphosphate (FBP) or glucose-6-phosphate (Glc6-P) increases the affinity of HPrSerP to CcpA at least twofold, but have no effect on CrhP-CcpA binding. Saturation of binding of CcpA to cre as studied by fluorescence and SPR is dependent on 50 microm of HPrSerP or > 200 microm CrhP. The rate constants of HPrSerP-CcpA-cre complex formation are k(a) = 3 +/- 1 x 10(6) m(-1).s(-1) and k(d) = 2.0 +/- 0.4 x 10(-3).s(-1), resulting in a K(D) of 0.6 +/- 0.3 nm. FBP and Glc6-P stimulate CcpA-HPrSerP but not CcpA-CrhP binding to cre. Maximal HPrSerP-CcpA-cre complex formation in the presence of 10 mm FBP requires about 10-fold less HPrSerP. These data suggest a specific role for FBP and Glc6-P in enhancing only HPrSerP-mediated CCR.     

The binding of divalent cations to myosin.

Centrifuge transport, equilibrium dialysis, and electron paramagnetic resonance studies on the binding of Mn2+ to myosin revealed two sets of noninteracting binding sites which are characterized at low ionic strength (0.016 M KCl) by affinity constants of 10(6) M-1 (Class I) and 10(3) M-1 (Class II), respectively. At 0.6 M KCl concentration, the affinity of Mn2+ for both sets of sites is reduced. The maximum number of binding sites is 2 for the high affinity and 20 to 25 for the low affinity set. Other divalent metal ions displace Mn2+ from the high affinity sites in the following order of effectiveness: Ca greater than Mg = Zn = Co greater than Sr greater than Ni. The inhibitory effects of Mg2+ and Ca2+ upon the Mn2+ binding are competitive with inhibitor constants of 0.75 to 1 mM which is similar to that of the low affinity divalent metal ion binding sites. Exposure of myosin to 37 degrees partially inhibits Mn2+ binding to Class I parallel with inhibition of ATPase activity. The binding of Mn2+ to the high affinity binding sites is not significantly influenced by ADP or PPi, although Mn2+ increases the affinity of ADP binding to myosin at high ionic strength.     

Comparison of several linear fluorophore- and quencher-conjugated oligomer duplexes for stability, fluorescence quenching, and kinetics in vitro and in vivo in mice

A useful property of optical imaging is the potential to modulate the detectable signal to improve target/nontarget ratios. When administered as a dimer of a fluorophore- and a quencher-conjugated duplex arranged to inhibit fluorescence but designed to dissociate only in the presence of its target, the fluorescence signal should in principle appear only in the target. This laboratory has demonstrated the feasibility of this approach by using a duplex consisting of a linear oligomer conjugated with Cy5.5 (emitter) hybridized to another linear oligomer conjugated with Iowa Black (quencher) in a pretargeting optical study. Now eight duplexes consisting of combinations of 18 mer linear phosphodiester (PO) and phosphorothioate (PS) DNAs and phosphorodiamidate morpholinos (MORFs) conjugated with Cy5.5 (emitter) and Iowa Black (quencher) were variously screened for in vitro duplex stability. The MORF/PO duplex was selected for further study based on evidence of stability in 37 degrees C serum. Simultaneously, the kinetics of quenching were investigated in vitro and in vivo in mice. Thereafter, mice were implanted in one thigh with MORF/PO Cy 5.5 microspheres and the complementary PS Iowa Black administered iv to measure the extent and kinetics of duplex formation in the target. While all duplexes were stable in buffer, only the MORF/PO duplexes and possibly all PS containing duplexes were stable in 37 degrees C serum for at least 4 h. The kinetics of quenching were found to be rapid in vitro, with a 80-90% decrease in Cy5.5 fluorescence immediately following formation of a PS/PS homoduplex, and in vivo, with a 27 to 38% decrease in target thigh/nontarget ratio within 1 h following administration of the complementary PS Iowa Black complementary DNA but not the random control DNA to mice implanted with MORF/PO Cy5.5 microspheres. This investigation has provided additional evidence that Cy5.5 may be efficiently and rapidly quenched by Iowa Black when both are conjugated to complementary oligomers and that the resulting inhibition of fluorescence is sufficiently persistent for imaging.     

Synthesis and in vitro characterization of a dendrimer-MORF conjugate for amplification pretargeting

Amplification pretargeting can play an important role in molecular imaging by significantly increasing the accumulation of signal in target tissues. Multiple-step amplification pretargeting offers the potential to greatly improve target localization of effector molecules through the intermediate use of polymers conjugated with multiple copies of complementary oligomers. In this study, PAMAM dendrimer generation 3 (G3) was conjugated with multiple copies of a phosphorodiamidate morpholino (MORF) oligomer. Characterization of the conjugate by native-PAGE and SE-HPLC demonstrated that the conjugation was successful. The average numbers of MORF groups in the G3-MORF conjugate, both attached and accessible to the (99m)Tc labeled complementary MORF (cMORF), were determined. The antitumor antibody CC49 was conjugated with both MORF and cMORF (collectively (c)MORF) at an average of about one group per molecule. Nine of the 32 carboxyl groups of the dendrimer were modified with MORF, of which 90% were accessible in solution to (99m)Tc-cMORF. After purification, the G3-MORF was radiolabeled with tracer (99m)Tc-labeled cMORF (i.e., G3-MORF/(99m)Tc-cMORF) and added to the antibody CC49 previously conjugated with cMORF (i.e., CC49-cMORF/G3-MORF/(99m)Tc-cMORF), the complex demonstrated a single peak on SE-HPLC as evidence of complete hybridization between G3-MORF/(99m)Tc-cMORF and CC49-cMORF. The CC49-(c)MORF were bound to both Protein G and Protein L coated plates, and G3-MORF was added to hybridize with CC49-cMORF before the (99m)Tc-cMORF was added to test amplification pretargeting. In comparison to conventional pretargeting without the G3-MORF, the signal was amplified about 6 and 14 times, respectively, showing that the G3-MORF participated in amplifying the signal. Further amplification studies using the CC49-(c)MORF for LS174T tumor cells in tissue culture also demonstrated clear evidence of signal amplification.     

Quantitative relation between intermolecular and intramolecular binding of pro-rich peptides to SH3 domains

Flexible linkers are often found to tether binding sequence motifs or connect protein domains. Here we analyze three usages of flexible linkers: 1), intramolecular binding of proline-rich peptides (PRPs) to SH3 domains for kinase regulation; 2), intramolecular binding of PRP for increasing the folding stability of SH3 domains; and 3), covalent linking of PRPs and other ligands for high-affinity bivalent binding. The basis of these analyses is a quantitative relation between intermolecular and intramolecular binding constants. This relation has the form K(i) = K(e0)p for intramolecular binding and K(e) = K(e01)K(e02)p for bivalent binding. The effective concentration p depends on the length of the linker and the distance between the linker attachment points in the bound state. Several applications illustrate the usefulness of the quantitative relation. These include intramolecular binding to the Itk SH3 domain by an internal PRP and to a circular permutant of the alpha-spectrin SH3 domain by a designed PRP, and bivalent binding to the two SH3 domains of Grb2 by two linked PRPs. These and other examples suggest that flexible linkers and sequence motifs tethered to them, like folded protein domains, are also subject to tight control during evolution.     

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.