Multivalently interactive molecular assembly, capturing agent, drug carrier, calcium chelating agent, and drug enhancer

Information

  • Patent Application
  • 20040162275
  • Publication Number
    20040162275
  • Date Filed
    October 07, 2003
    21 years ago
  • Date Published
    August 19, 2004
    20 years ago
Abstract
A multivalently interactive molecular assembly having a plurality of functional groups or ligands, in which a ratio between Rh and Rg expressed as Rh/Rg is 1.0 or less. Here, Rh is a hydrodynamic radius calculated from dynamic light scattering (DLS) assay performed in aqueous solution; and Rg is a radius of gyration determined based on the Zimm plot generated using data obtained by static light scattering (SLS) assay.
Description


BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention


[0002] The present invention relates to a multivalently interactive molecular assembly which can effectively and stably bind to a target substance in vivo or in vitro, a capturing agent comprising said multivalently interactive molecular assembly for capturing an object of interest in vivo or in vitro, a drug carrier which aids administration of a drug, a calcium chelating agent which can effectively chelate calcium, and a drug enhancer which can be administered with a drug to assist in, for example, absorption of the drug.


[0003] 2. Description of the Related Art


[0004] Currently, compounds which comprise ligands having with high affinity for a variety of receptors in vivo are of great interest as novel medicaments since those can affect various functions of those receptors. To obtain such a compound comprising ligands having high affinity for receptors, researchers have made intense studies to develop a variety of such low-molecular weight compounds as well as high-molecular weight compounds containing a great number of ligands which can interact multivalently. However, the conventional low-molecular weight compounds or the water-soluble high molecular weight compounds that comprise any ligands interactive with receptors had limited binding stability and efficiency and thus could not exhibit sufficient interaction multivalency. Particularly, the low-molecular weight compounds had insufficient binding stability since only the limited number of ligands could be incorporated therein. The conventional water-soluble high-molecular weight compounds could have many ligands incorporated therein. However, such conventional high-molecular weight compounds containing many ligands could not be expected to bind effectively and stably to the target receptors. This is because such a high-molecular weight compounds may have a great flexibility and this property tends to associate with each other via hydrophobic interaction of the ligands in the conjugates which leads to form inter- and intra-molecular aggregation having the water-soluble high-polymer molecule as its outer shell. Moreover, both of those low- and high-molecular weight compounds are not degradable, and it was thus impossible to control their binding strength to their targets. Therefore, one has needed the development of a compound comprising ligands having high binding stability (especially those having a binding stability that is controllable in terms of space and time).


[0005] Resins comprising repeated acrylic acid units (carbomer and polycarbophil) are known to be useful as drug enhancers to increase transmucosal-permeability of protein- or peptide-type drugs. Polyacrylate resins chelate calcium and thereby open the tight-junction of small intestine epithelium. Further, the polyacrylate resins chelate calcium from proteases such as trypsin or chymotrypsin, thereby inhibiting decomposition of protein in an intestinal lumen. As described above, a method for chelating calcium using polyacrylic acid may inhibit the decomposition of a protein and facilitate the permeation of the protein through gastrointestinal tract. However, it has also been reported that the direct binding between polyacrylic acid and enzyme may be the key factor in inhibition of protease activity. This report suggests that an intermolecular bond (e.g., hydrogen bond or electrostatic interaction) via carboxyl group rather than calcium chelation may play an important role in the biological activities. Although polyacrylic acid has useful properties such as calcium chelating ability and non-specific interaction, they were disadvantageous in that these properties can not be controlled. Therefore, it has been needed to develop novel materials of which chelating ability and physical interaction with biological component(s) are controllable and binding to mucosa, drug permeability and protease inhibition can be regulated.



SUMMARY OF THE INVENTION

[0006] The present invention aims at solving the above-described problems in the prior art and attaining the object described below. In summary, the object of the present invention is to provide a multivalently interactive molecular assembly which can effectively and stably bind to a target substance in vivo or in vitro, a capturing agent comprising said multivalently interactive molecular assembly for capturing an object of interest in vivo or in vitro, a drug carrier which aids administration of a drug, a calcium chelating agent which can effectively chelate calcium, and a drug enhancer that can be administered with a drug to assist in, for example, the absorption of the drug.


[0007] The present inventors found that a compound with a small flexibility (e.g., a multivalently interactive molecular assembly comprising a plurality of cyclic molecules, a linear molecule that is threaded through the cyclic molecules to hold them together, and capping bulky substituents at the both ends of the linear molecule) did not intramolecularly associate in aqueous conditions even when a great number of functional groups or ligands have been incorporated therein. Also the compound could effectively and stably bind to its target substance(s), and the binding stability of such a compound could be controlled by regulating the amount of the functional groups and/or ligands to be incorporated therein. They also found that, when desired, biodegradable groups can be used as said bulky substituents to reduce the binding multivalency since the in vivo decomposition of the biodegradable groups may lead to the destruction of the entire supramolecular backbone itself, whereby the binding stability of the compound to its target substance(s) is controllable in terms of time and space.


[0008] The present inventors also found that polyrotaxane containing, as functional group, carboxyl group incorporated therein can chelate calcium and thus inhibit trypsin activity.


[0009] The present invention was developed based on these findings. Hereinafter, means for solving the above-described problems will be described.


[0010] In summary, a first aspect of the present invention provides a multivalently interactive molecular assembly comprising a plurality of functional groups and/or ligands, characterized by that Rh/Rg, which is the ratio between hydrodynamic radius (Rh) calculated from dynamic light scattering (DLS) assay performed in aqueous solution and radius of gyration (Rg) determined based on the Zimm plot generated using data obtained by static light scattering (SLS) assay, is equal or lower than 1.0.


[0011] The ratio (Rh/Rg) may preferably be from 0.20 to 0.60.


[0012] A second aspect of the present invention provides a multivalently interactive molecular assembly comprising a plurality of functional groups and/or ligands, characterized by that the diffusion constant (D) value calculated from the DLS assay performed in aqueous solution may increase as the scattering vector constant (K) increases.


[0013] A third aspect of the present invention provides a multivalently interactive molecular assembly comprising a plurality of cyclic molecules, a linear molecule which is threaded through the cyclic molecules to hold them together, and capping bulky substituents at the both ends of the linear molecule, characterized by that at least tow of said a plurality of cyclic molecules are substituted with the functional group and/or the ligand. A ratio of a spin-spin relaxation time (T2) measured on the substituent, to a spin-spin relaxation time (T2) measured on a substituent linked with a free cyclic molecule, is in a range of from 0.4 to 1. Here, the spin-spin relaxation time (T2) of the substituent linked with the free cyclic molecule is measured at a moiety thereof that corresponds to the measured moiety within the substituent in multivalently interactive molecular assembly. Moreover, the above-mentioned “free cyclic molecule” is a cyclic molecule that is not threaded through with the linear molecule.


[0014] Preferably, the bulky substituents can be introduced to the linear molecule via biodegradable linkages thus cleaved from the latter.


[0015] The elution time of the multivalently interactive molecular assembly according to the present invention in gel permeation chromatography at a flow rate of 1 ml/min or less may be 1 to 30 minutes shorter than that of any of the cyclic molecules, linear molecules and bulky substituents.


[0016] Preferable compounds of multivalently interactive molecular assembly according to the present invention are polyrotaxanes.


[0017] The cyclic molecules may preferably be cyclodextrins.


[0018] On spectra of one-dimensional 1H-NMR spectroscopy, glucose C3 and C5 protons present in the cavity of the cyclodextrins may preferably exhibit a 0.1 to 1.0 ppm upfield or downfield shift when compared to those present in the cavity of free cyclodextrin.


[0019] The linear molecule threading through the cyclodextrin cavities may preferably exhibit a 0.01 to 1.0 ppm upfield or downfield shift when compared to the linear molecule that is not threading through the cyclodextrin cavities as determined by one-dimensional 1H-NMR spectroscopy.


[0020] Preferably, as determined by a two-dimensional 1H-NMR spectrum, a cross peak caused by the nuclear Overhauser effect between glucose C3 and C5 protons present in the cavity of the cyclodextrin and protons present in the linear molecule may be detected, and those chemical shifts may be 3.0 to 4.0 ppm for the C3 and C5 protons and 1.0 to 6.0 ppm for the linear molecule respectively.


[0021] Preferably, there is no detectable melting peak of the linear molecule in the DSC chart of differential scanning calorimetry.


[0022] The functional group may preferably contain a caboxyl group at an end thereof.


[0023] Preferable example of functional group containing a caboxyl group at an end thereof may be carboxyalkoxycarbonyl group.


[0024] The ligand may be sugar ligand.


[0025] A fourth aspect of the present invention provides a multivalently interactive molecular assembly in which a plurality of cyclodextrin molecules are threaded through a linear molecule capped with bulky substituents, characterized by that, in at least two of the cyclodextrin molecules, C6 primary hydroxyl group, C2 secondary hydroxyl group and C3 secondary hydroxyl group each have a peak area which is reduced by 10 to 95% compared to that of the corresponding hydroxyl group in a cyclodextrin with no substituent as determined by two-dimensional 1H-NMR spectroscopy.


[0026] Multivalently interactive molecular assemblies according to the present invention may preferably be used as a capturing agent which can capture an object of interest.


[0027] A multivalently interactive molecular assembly according to the present invention may preferably be used as a drug carrier.


[0028] A multivalently interactive molecular assembly according to the present invention may preferably be used as a calcium chelating agent.


[0029] Alternatively, a multivalently interactive molecular assembly according to the present invention may preferably be used as a drug enhancer.


[0030] A capturing agent according to the present invention can capture an object of interest and comprises at least the above-described multivalently interactive molecular assembly according to the present invention.


[0031] A drug carrier according to the present invention can be bound to a drug and comprises at least the above-described multivalently interactive molecular assembly according to the present invention.


[0032] A calcium chelating agent according to the present invention can chelate calcium and comprises at least the above-described multivalently interactive molecular assembly according to the present invention which contains a functional group having a caboxyl group at an end thereof.


[0033] A drug enhancer according to the present invention can be used to enhance the efficacy of the drug and comprises at least the above-described multivalently interactive molecular assembly according to the present invention that contains a functional group having a caboxyl group at an end thereof.


[0034] Polyrotaxane according to the present invention may be used in the above-described multivalently interactive molecular assembly according to the present invention.







BRIEF DESCRIPTION OF THE DRAWINGS

[0035]
FIGS. 1A through 1E show the results obtained by gel permeation chromatography (GPC).


[0036]
FIGS. 2A through 2C show the results obtained by 750 MHz 1H-NMR spectroscopy.


[0037]
FIG. 3 shows a schematic view of a biotin-polyrotaxane conjugate and a streptavidin-immobilized surface illustrating the binding of the two.


[0038]
FIG. 4 shows SPR-curves illustrating the binding of biotin-polyrotaxane conjugate to the streptavidin-immobilized surface.


[0039]
FIG. 5 shows SPR-curves illustrating the binding/dissociation of biotin-polyrotaxane conjugate.


[0040]
FIG. 6 shows linear plots illustrating dissociation constant between streptavidin and biotin-polyrotaxane conjugate determined from the dissociation curves in FIG. 3.


[0041]
FIGS. 7A and 7B show inhibition curves illustrating the binding inhibition of streptavidin to the biotin-immobilized sensor surface by the biotin molecule in the conjugate.


[0042]
FIG. 8 shows the relationship between the fractional inhibition and conjugate concentration.


[0043]
FIGS. 9A and 9B show conceptual views of binding.


[0044]
FIG. 10 shows the results obtained by 1H-NMR analysis of 132CEE-α/E4-PHE-Z.


[0045]
FIG. 11 shows the results obtained by GPC of 132CEE-α/E4-PHE-Z and 6CEE-α-CD.


[0046]
FIG. 12 shows the solubility of 132CEE-α/E4-PHE-Z and 6CEE-α-CD in PBS at different pH conditions.


[0047]
FIG. 13 shows the results obtained by calcium binding assay.


[0048]
FIG. 14 shows the effects of various compounds including “CEE-Polyrotaxane” on trypsin activity.


[0049]
FIG. 15 shows trypsin inhibition factors (IFs).


[0050]
FIG. 16 shows the effects of the length of poly(ethylene glycol) chain on trypsin inhibition.


[0051]
FIG. 17 shows the IF values (representing trypsin inhibition) for CEE-polyrotaxanes with different number of α-CDs.


[0052]
FIG. 18 shows a change in a transmissivity of the solution containing CEE-polyrotaxane and trypsin, with (b) or without (a) the existence of an excess amount of calcium chloride.


[0053]
FIG. 19 shows a diagram illustrating the inhibition of hemagglutination by various Mal-polyrotaxane conjugates.


[0054]
FIG. 20 shows the relationship between the threading ratio α-CD and the inhibitory effect.


[0055]
FIG. 21 shows the chemical structure of maltose-polyrotaxane conjugates consisting of α-CDs, PEG, benzyloxycarbonyl-tyrosine and maltose (Mal-R/E20-TYRZs, 1-3), maltose-R-CD (4), and maltose-poly(acrylic acid) (5) conjugates.


[0056]
FIG. 22 shows the synthesis of maltose-polyrotaxane conjugates.


[0057]
FIG. 23 (a) shows the GPC charts of the maltose-polyrotaxane conjugates (1d, 2d and 3d), the maltose-α-CD conjugate (4) and the maltose-poly(acrylic acid) conjugates (5d). (b) shows the calibration curve of pullulan standard.


[0058]
FIG. 24 shows the 1H-NMR charts of 1d.


[0059]
FIG. 25 shows the 1H-NMR charts of 2d.


[0060]
FIG. 26 shows the 1H-NMR charts of 3d.


[0061]
FIG. 27 shows the 1H-NMR charts of 4.


[0062]
FIG. 28 shows the 1H-NMR charts of 5d.


[0063]
FIG. 29 shows the relation between the spin-spin relaxation time (T2) of maltose-ligand and the relative potency of Con-A-induced hemagglutination inhibition based on the minimum inhibitory concentration (MIC) of the maltose unit.


[0064]
FIG. 30 shows the T2







DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0065] The first aspect of a multivalently interactive molecular assembly according to the present invention may comprise a plurality of functional group(s) and/or ligand(s), and be characterized by that (Rh/Rg), the ratio between radius of gyration (Rg) calculated based on the Zimm plot generated using data obtained by static light scattering (SLS) assay and a hydrodynamic radius (Rh) calculated from dynamic light scattering (DLS) assay performed in aqueous solution, is equal or lower than 1.0. The ratio (Rh/Rg) may preferably be from 0.20 to 0.60.


[0066] Conventional multivalently interactive molecular assembly such as spherical micelles, liposomes and particles had a ratio (Rh/Rg) of 1.28 to 1.30. Conventional polymeric multivalently interactive molecular assemblies generally take a spherical form (which is energy-stable) and may thus intramolecularlly associated with each other when many functional groups and/or ligands have been incorporated therein. Therefore, only the limited number of functional groups and/or ligands are available for association with their target(s), which resulted in low binding stability. On the contrary, a multivalently interactive molecular assembly according to the present invention having a small flexibility may have a small intramolecular association and can therefore bind effectively and stably to the target substance(s) even when many functional groups and/or ligands have been incorporated therein.


[0067] Dynamic light scattering (DLS) and static light scattering (SLS) can be determined using a light scattering analyzer DLS7000 (available from Otsuka Electronics Co., Ltd.) with a He—Ne laser (at 630 nm, 10 mW) for static light scattering or an Ar laser (at 488 nm, 75 mW) for dynamic light scattering as a light source. Hydrodynamic radius (Rh) and radius of gyration (Rg) can be calculated by any known methods.


[0068] Any atom or atomic group can be used as the above-described functional groups which may be involved in reaction characteristic to the above-described multivalently interactive molecular assembly, and can be suitably selected depending on a particular purpose. Examples of such functional groups include any heteroatoms except for carbon and hydrogen, atomic groups containing any one or more of these heteroatoms, and structures containing multiple bond(s) between carbon atoms. Particular examples include, for example, hydroxyl, alkoxy (such as methoxy, n-butoxy, n-octyloxy, methoxyethoxy or benzyloxy), alkenyloxy, alkynyloxy, aryloxy (such as phenoxy, p-tolyloxy, 4-methoxyphenoxy or 4-t-butylphenoxy), formyl, keto, acyl, aroyl, carboxyl, alkoxycarbonyl (such as methoxycarbonyl, n-butoxycarbonyl or 2-ethylhexyloxycarbonyl), alkenyloxycarbonyl, alkynyloxy carbonyl, aryloxy carbonyl, alkylsulfonyl (such as n-butylsulfonyl or n-dodecylsulfonyl), arylsulfonyl (such as p-tolylsulfonyl, p-dodecylphenylsulfonyl or p-hexadecyloxyphenylsulfonyl), aminoacyl, amino, cyano, imidoyl, mercapto, nitro and sulfone groups, halogen atom, sulfide-bond-containing groups, disulfide-bond-containing groups, C═C bond-containing groups, C≡C bond-containing groups, and carboxylic anhydride residue, imide residue (such as succinimide ester) and the like. Such the functional groups may also include activated groups such as N-acylimidazole, succinimide ester, p-nitrophenyl ester, pentafluorophenyl ester, methyl ester, tosyl, aldehyde, allyl, methacryl, acryl, halogenated alkyl, isocyanate and thiol groups. These groups may be substituted with any of the aforementioned groups.


[0069] In all the functional groups, amino group that may be substituted, carboxyl group that may be substituted, hydroxyl group or any groups that have been substituted with any of these groups are preferable.


[0070] There is no limitation for using any ligand if they can specifically bind to its receptor in vivo or ill vitro, and can be suitably selected depending on a particular purpose. The terms “ligand” and “receptor” are conceptually used in relation to each other. Therefore, ligand and receptor should not be considered separately but in combination of two materials that can bind to each other. Examples of ligands or receptors include peptides, saccharides, glycoproteins, lipids, glycolipids, nucleic acids, amino acids, low-molecular weight compounds and ions. Combination of ligand and receptor may include any combination of those substances, including: peptide and peptide; peptide and saccharide; saccharide and peptide; saccharide and nucleic acid; and so on. Unlimiting examples of such combination will be listed in Table 1.
1TABLE 1LigandReceptorTyroxine-phosphorylatedSH2 domain, PTB domainpolypeptideGTP-binding protein which isRho GDIassociated with GDP which canbe substituted by GTP viaguanine nucleotide exchanger(e.g., Rh)GTP-binding protein which isTarget molecule (e.g., Raf serineassociated with GTP which canthreonine kinase for Rasbe converted into GDP by GTPhydrolase (e.g., Ras)Growth factor, cytokineGrowth factor receptor, cytokinereceptorAntigenAntibodyLow molecular weightProtein kinase C,metabolite, second messenger orcAMP-dependent kinase,ioncalmodulinSugar ligand such as glucose,Asialoglycoprotein receptormannose and maltoseSialic groupSialic acid receptor


[0071] These functional groups or ligands may bind to the cyclic compound threaded onto the linear compound, directly or via another functional groups.


[0072] The second aspect of a multivalently interactive molecular assembly according to the present invention may comprise a plurality of functional group(s) and/or ligand(s), and be characterized by that the diffusion constant (D) value calculated from dynamic light scattering assay performed in aqueous solution may increase as the scattering vector constant (K) value increases. On the contrary, conventional spherical micelles, liposomes or particles have a consistent (D) value regardless of the (K) value.


[0073] The third aspect of a multivalently interactive molecular assembly according to the present invention may comprise a plurality of cyclic molecules, a linear molecule that is threaded through the cyclic molecules to hold them together, and capping bulky substituents at the both ends of lie linear molecule, and be characterized by that at least two of said a plurality of cyclic molecules are substituted with a functional groups and/or ligands.


[0074] This structure may have a property of small flexibility and accompanying advantageous properties, and allow the many cyclic molecules threaded onto the linear molecule to slide along and rotate around the linear molecule, which facilitates target capturing.


[0075] Any linear molecules that can be threaded through a plurality of cyclic molecules to hold them together may be used, including hydrophilic or hydrophobic polymers such as polyethylene glycol (PEG), polypropylene glycol (PPG), block random copolymers thereof, poly(amino acids), polysaccharides and fatty acids. Particularly, PEG may be preferably used as a liner molecule since it can be capped with bulky substituents easily Preferably the bulky substituents are enough to cap the both ends of the linear molecule to arrest said a plurality of cyclic molecules, including amino acid, oligopeptide, monosaccharide, oligosaccharide, nucleic acid and fluorescent molecule. Particular but unlimiting examples include: oligopeptide comprising repeated unit of any one or more selected from the group consisting of N-benzyloxycarbonyl-L-phenylalanine, alanine, valine, leucine, isoleucine, methionine, proline, phenylalanine, tryptophan, asparatic acid, glutamic acid, glycine, serine, threonine, tyrosine, cysteine, lysine, arginine and histidine, or derivative thereof.


[0076] Bulky substituents may preferably be linked to the linear molecule via biodegradable linkages so that the former can be degraded in vivo and thus cleaved from the latter. When the bulky substituents are attached to the both ends of polyrotaxane via a linkage that can be enzymatically or non-enzymatically hydrolyzed (e.g., peptide, amide, ester or phosphodiester bond), hydrolysis of the linkage may release cyclodextrin to the medium over a certain period of time such as from minute to months. In this case, hydrolysis time can be set at on the order of from minute to months. The hydrolysis can be analyzed by, for example, GPC, reverse-phase chromatography or NMR.


[0077] In terms of introduction of such bulky biodegradable groups, conventional multivalent binding polymer compound had an disadvantage that the biodegradation of the substituents will be prevented or hindered since enzyme can hardly access to the substituents due to steric hindrance caused by hydrophobic interactions formed in the molecule while the inventive multivalently interactive molecular assembly has an advantage that enzymes can easily access to the ends of the linear molecule to cleave the substituents therefrom due to the small folding and association tendencies of the molecule.


[0078] There are no limitation of cyclic molecules if they have at least one of functional groups and/or ligands, including, for example, cyclodextrin (CD), crown ether and cyclofructan. In these molecules, cyclodextrin is preferable. Examples of cyclodextrin include α-, β- and γ-cyclodextrins with different number of glucose unit.


[0079] Functional groups and/or ligands can be introduced into cyclodextrin via the hydroxyl group in the cyclodextrin. Such functional groups or ligands may be linked to the hydroxyl group directly or via another functional groups. For example, in the biotin-containing multivalently interactive molecular assembly shown in Structural Example 1 below, the biotin (i.e., ligand) may be introduced into the assembly by linking the hydrazide group in biotin hydrazide to the hydroxyl group of the cyclodextrin via a carbamoyl bond derived from N,N′-carbonyldiimidazole (CDI). Alternatively, 2-aminoethanol may be linked to the cyclodextrin via the carbamoyl bond.
1


[0080] On spectra of one-dimensional 1H-NMR spectroscopy, glucose C3 and C5 protons present in the cavity of cyclodextrin may preferably exhibit a 0.1 to 1.0 ppm upfield or downfield shift when compared to those present in the cavity of free cyclodextrin. The linear molecule threading through the cyclodextrins may preferably exhibit an upfield or downfield shift when compared to a linear molecule which is not threading through cyclodextrins as determined by the one-dimensional 1H-NMR spectroscopy.


[0081] All the peaks derived from the multivalently interactive molecular assembly in which the polymeric chain is threaded through the cyclodextrin cavity may be approximately 0.01 to 0.5 ppm broader than those derived from the one in which the polymeric chain is not threading through the cyclodextrin cavity.


[0082] In two-dimensional 1H-NMR spectrum, a cross peak caused by the nuclear Overhauser effect between glucose C3 and C5 protons present in the cavity of the cyclodextrin and protons present in the linear molecule. Its chemical shifts were within the range of 3.5 to 4.0 ppm where C3 and C5 protons were observed and 1.0 to 6.0 ppm where the linear molecule was detected.


[0083] According to the DSC chart of differential scanning calorimetry (DSC) assay, no melting peak of the linear molecule was detected in the multivalently interactive molecular assembly comprising cyclodextrins and a linear molecule threaded therethrough while a melting peak of the linear molecule was observed in a mixture of cyclodextrins and polymer chain. A multivalently interactive molecular assembly comprising a PEG or PEG copolymer chain as the linear molecule may have a melting temperature of 0 to 200° C.


[0084] Multivalently interactive molecular assembly may preferably be polyrotaxane.


[0085] The elution time of the multivalently interactive molecular assembly may preferably be 1 to 30 minutes shorter than that of any of the cyclic molecule, linear molecule and bulky substituents as determined by gel permeation chromatography at a flow rate ≦1 ml/min. Tie difference in elution time may depend on the number of cyclodextrin threaded onto the linear molecule. Any suitable column that is commercially available can be used in gel permeation chromatography, including Bio-Rad Bio-Sil SEC 125-5, GF-710HQ, Showa Denko Co. Ltd., Sephadex G-50, G-75, G-25, G-10, Tosoh, GMPWXL or the like.


[0086] The fourth aspect of a multivalently interactive molecular assembly according to the present invention may comprise a plurality of cyclodextrin, a linear molecule which is threaded through the plurality of cyclodextrins to hold them together, and capping bulky substituents at the both ends of the linear molecule, and be characterized by that, in at least two of the cyclodextrin molecules, C6 primary hydroxyl group, C2 secondary hydroxyl group and C3 secondary hydroxyl group each have a peak area which is reduced by 10 to 95% compared to that of the corresponding hydroxyl group in a cyclodextrin without substituent as determined by two-dimensional 1H-NMR spectroscopy. This is because multiple functional groups and ligands that can interact with receptors have been incorporated into the hydroxyl group of cyclodextrin, thereby reducing the peak areas of C6 primary hydroxyl group, C2 secondary hydroxyl group and C3 secondary hydroxyl group of cyclodextrin by 10 to 95%.


[0087] In the multivalently interactive molecular assembly according to the present invention, the functional groups may preferably contain carboxyl group in terms of calcium chelating ability and trypsin inhibition activity. Calcium chelating ability and trypsin inhibition activity have been verified by the calcium binding assay and trypsin inhibition activity described below. Examples of carboxyl group-containing functional groups include carboxyalkoxy carbonyl group and preferably carboxy ethoxy carbonyl group.


[0088] Functional polyrotaxane, one example of multivalently interactive molecular assemblies according to the present invention, can be produced by synthesizing a polyrotaxane scaffold, and then introducing functional groups and/or ligands by which receptors may be caught in the hydroxyl group of α-CDs in the scaffold. Polyrotaxane, in which α-CDs are threaded through the polyoxyethylene chain capped with benzyloxycarbonyl-phenylalanine (Z-L-Phe) groups, can be prepared according to any known method. In summary, α-CD/polyoxyethylene (PEO-BA) inclusion complex was prepared by simply mixing a saturated aqueous solution of α-CD and an aqueous solution of PEO-BA. Next, succinimide ester of Z-L-Phe prepared by condensation reaction of Z-L-Phe with N-hydroxy succinimide may be allowed to react with the terminal-amino group of the inclusion complex dissolved in DMSO to synthesize a polyrotaxane scaffold containing approximately 22 of α-CDs.


[0089] Introduction of ligand will be described referring to the synthesis of biotin-polyrotaxane conjugate as an example. Structural Example 2 below shows one exemplary synthesis of biotin-polyrotaxane conjugate.
23


[0090] In order to introduce biotin molecules into the polyrotaxane scaffold, the hydroxyl group of α-CDs in the polyrotaxane may be activated by N,N′-carbonyldiimidazole (CDI) so that it can be reacted with the hydrazide group of biotin hydrazide.


[0091] The CDI-activated polyrotaxane (one polyrotaxane molecule contains 22 α-CDs and 0.24 mM N-acylimidazole groups) may be dissolved in 2 mL of dry DMSO, and 0.24 mM biotin hydrazide and 0.24 mM HOBt may be added to the solution under nitrogen atmosphere. The mixture solution is then stirred at room temperature for 24 hours, added dropwise with 9.9 mM 2-aminoethanol, and then stirred under the same conditions for additional 24 hours. The resulting reaction solution may be dialyzed against water through a dialysis membrane (Spectra/Pro® MWCO; 1000) and lyophilized to give biotin-polyrotaxane conjugate.


[0092] Alternatively, carboxyethyl ester-polyrotaxane complex was prepared by introducing carboxyethyl ester into polyrotaxane utilizing reaction between the hydroxyl group of the polyrotaxane and succinic anhydride in pyridine.


[0093] The multivalently interactive molecular assembly according to the present invention may have a high binding stability. Particularly, the binding stability is controllable in terms of space and time. The present inventors used SPR technique to analyze the binding/dissociation constant between the biotin-polyrotaxane conjugate and streptavidin as the model of multivalent ligands targeting to biological receptors. As the number of biotin linked to one polyrotaxane molecule increased, dissociation constant (kdiss) decreased rather than binding constant (kbind) increased, assuming a pseudo-first-order kinetics. Dissociation did not follow the pseudo-first-order kinetics, and re-binding of biotin-polyrotaxane conjugate to the streptavidin-deposited surface was observed. The results of competitive inhibition assay showed that the biotin-polyrotaxane conjugate had a stronger inhibition activity than that of biotin-α-CD conjugate. While a biotin-α-CD conjugate may interact monovalently, a biotin-polyrotaxane conjugate containing biotin-α-CDs can interact multivalently, thereby providing multivalent kinetics. Desirable binding stability of the multivalently interactive molecular assembly can be obtained by regulating multivalency thereof when it is synthesized. Optionally, the capping bulky substituents may be designed so that they are decomposed under certain conditions to control dissociation of the cyclic molecules from the linear molecule, thereby obtaining desirable binding stability. I this way, the multivalently interactive molecular assembly according to the present invention may have a high binding stability. Particularly, the binding stability of the inventive assembly is controllable in terms of time and space.


[0094] The spin-spin relaxation time (T2) is, namely, a time required by a molecule to stabilize energy of nucleus-spin. Longer the spin-spin relaxation time (T2) is, more active the mobility of the molecule is. Accordingly, measuring T2 of a substituent, e.g., a ligand or a functional group, can indicate a molecular mobility of the substituent. When a substituent is linked with a polymer, generally, the mobility of the substituent is reduced and T2 is reduced down to one-tenth or less. A substituent linked with the multivalently interactive molecular assembly of the present invention, however, maintains substantially the same level of the mobility compared to the mobility of the substituent before linking by controlling the number of cyclic molecule relative to a certain length of linear molecule, or the number of substituent relative to a cyclic molecule. It is also found out from the result of the analysis that a mobility of a substituent indicated by T2 is closely related to an affinity of a ligand to a receptor.


[0095] T2 is, for example, measured by Pulse NMR analysis or the like, using Carr-Purcell-Meiboom-Gill sequence. Owing to determine T2 of a substituent, it is preferable to measure a receptor-linkage moiety within the substituent, which exhibits the mobility thereof the most clearly. However, a measuring method of T2 is not limited thereto, and it can be suitably selected from the viewpoint of simplicity or applicability of measuring, and the like.


[0096] In the present invention, a spin-spin relaxation time (T2) is measured on a substituent linked with a cyclic molecule of the multivalently interactive molecular assembly, and it is preferred that the ratio of the measured T2 of the substituent to a substituent linked with a free cyclic molecule, is in a range of from 0.4 to 1, preferably from 0.5 to 1, more preferably from 0.75 to 1, and further preferably from 0.9 to 1 from the viewpoint of affinity. Here, the substituent linked with the free cyclic molecule is a substituent linked with a cyclic molecule which is not threaded through with the linear molecule, and the spin-spin relaxation time (T2) is measured at a corresponding moiety thereof to the moiety to be measured in the substituent linked with the cyclic molecule within the multivalently interactive molecular assembly. In this way, an excellent multivalently interactive molecular assembly is suitably designed with considering molecular mobility of substituent, as well as the above-mentioned effect of multivalency.


[0097] A multivalently interactive molecular assembly according to the present invention can be used as a capturing agent that can capture its target or targets. The inventive multivalently interactive molecular assembly can be used as a capturing agent. By introducing the ones which may capture a target of capturing, either as functional group or ligand, it may be used as a capturing agent having high binding ability in which the binding ability is controllable.


[0098] A multivalently interactive molecular assembly according to the present invention can also be used as a drug carrier. The properties of the multivalently interactive molecular assembly are also useful for a drug carrier. Particularly, a drug can be introduced into the multivalently interactive molecular assembly via the functional group or ligand thereof to prepare a formulation that can then be administered to an organism. Optionally, the formulation can be designed so that the capping bulky substituents may be decomposed under certain conditions, thereby controlling the release of the drug from the polyrotaxane scaffold. Alternatively, the drug itself may act as the ligand.


[0099] A multivalently interactive molecular assembly having carboxyl group according to the present invention can be used as a calcium chelating agent or a drug enhancer. Such a multivalently interactive molecular assembly has abilities to inhibit trypsin activity and/or open the tight junction of small intestine via its calcium chelating activity and thus can be used as calcium chelating agent or drug enhancer. The multivalently interactive molecular assembly may also be useful for other biological effects of calcium chelating.


[0100] Any capturing agent can be used in the present invention which comprises at least a multivalently interactive molecular assembly according to the present invention and has an ability to capture its target or targets. An element to be introduced in the multivalently interactive molecular assembly can be suitably selected from any known materials.


[0101] Any drug carriers can be used in the present invention which comprises at least a multivalently interactive molecular assembly according to the present invention and can be bound to a drug. An element to be introduced in the multivalently interactive molecular assembly can be suitably selected from any known materials.


[0102] Any calcium chelating agents can be used in the present invention which contains at least a multivalently interactive molecular assembly according to the present invention and can chelate calcium. An element to be introduced in the multivalently interactive molecular assembly can be suitably selected from any known materials.


[0103] Any drug enhancers can be used in the present invention which comprises at least a multivalently interactive molecular assembly according to the present invention and can be used for assisting in the efficacy of drug. An element to be introduced in the multivalently interactive molecular assembly can be suitably selected from any known materials.



EXAMPLES

[0104] [Materials]


[0105] The α-cyclodextrin (α-CD) was purchased from Bio-Research Corporation of Yokohama (Yokohama, Japan). The α-(3-aminopropyl)-ω-(3-aminopropyl) polyoxyethylene (PEO-BA: Mn=4000) was kindly supplied by Sanyo Chemical Co, (Kyoto, Japan).


[0106] The benzyloxycarbonyl-phenylalanine (Z-L-Phe), 2-ethanol, N, N′-carbonyldiimidazole (CDI), formic acid and d-biotin were purchased from Wako Pure Chemical Co. Ltd. The N-hydroxysuccinimide and 1-hydroxybenzotriazole (HOBt) were purchased from Peptide Institute, Inc. (Osaka, Japan). Streptomyces avidinii derived streptavidin was purchased from Nacalai Tesque, Inc. (Kyoto, Japan). Phosphate buffered saline (pH 7.4) containing 0.05v/v % Tween 20 (PBS/T) (10 mM sodium phosphate, 2.7 mM calcium chloride, 138 mM sodium chloride and 0.05% Tween 20) was prepared by dissolving PBS/T powder purchased from Sigma Chemical Co. (St. Louis, USA) and kept at 4° C. until use. EZ-Link-Biotin Hydrazide™ and ImmunoPure® streptavidin were purchased from PIERCE (Rockford, USA). Biotin cuvettes for the interaction analysis system (IAsys) were purchased from Affinity Sensors Cambridge, Inc. (UK). Dimethylsulfoxide (DMSO) was purchased from Wako Pure Chemical Co., Ltd., and distilled by conventional method. The DMSO for the high performance liquid chromatography (HPLC) was purchased from Kishida Chemical Co. (Osaka, Japan). All the other chemicals used were of reagent grade.



Example 1

[0107] Synthesis of Biotin-Polyrotaxane and Biotin-α-CD Conjugates


[0108] Polyrotaxane, in which a plurality of α-CD, is threaded through a PEO chains capped with Z-L-Phe groups by any known method. Briefly, α-CD/PEO-BA inclusion complex was prepared by simply mixing a saturated aqueous solution of α-CD and an aqueous solution of PEO-BA. Next, a succinimide ester of Z-L-Phe, which was obtained by condensation reaction of Z-L-Phe and N-hydroxysuccinimide, is reactive with the terminal amino group of the inclusion complex dissolved in DMSO. The chemical structure was determined by 750 MHz 1H-NMR using a FT-NMR spectrometer (Varian FT-NMR Gemini 750, Palo Alto, USA). The number of α-CDs was determined to be approximately 22 based on the 1H-NMR spectrum by comparing the integration of the signal at 4.75 (C1H of α-CD) with one at 3.49 (CH2CH2O of PEO).


[0109] Next, to introduce biotin molecules into the polyrotaxane scaffold, the hydroxyl group of α-CDs in the polyrotaxane was activated by CDI so that the hydroxyl group could react with the hydrazide group of biotin hydrazide. Particularly, the polyrotaxane (13.6 μM, hydroxyl group 6.1 mM) was dissolved in 20 mL of dry DMSO, and 30.7 mM CDI was added to the solution, and then, the mixture was stirred at room temperature for 3 hours under nitrogen atmosphere. The reaction mixture was slowly added to an excess amount of ether, and the mixture was then precipitated, filtrated and dried under vacuum to give a CDI-activated polyrotaxane. The activation of the hydroxyl groups in the polyrotaxane was confirmed by calorimetric determination of imidazole after alkaline hydrolysis of N-acyl imidazole groups. The number of α-CDs per polyrotaxane molecule was approximately 22 and the degree of activation was approximately 10 per α-CD molecule. Therefore, the total degree of activation per polyrotaxane molecule is approximately 220, which indicates that hundreds of biotin can theoretically be incorporated into one polyrotaxane scaffold.


[0110] The CDI-activated polyrotaxane (one polyrotaxane contains 2 α-CDs and 0.24 mM N-acylimidazole group) was dissolved in 2 mL of dry DMSO, and 0.24 mM biotin hydrazide and 0.24 mM HOBt were added to the solution in the presence of nitrogen gas. The mixture solution was stirred at room temperature for 24 hours, added dropwise with 9.9 mM 2-aminoethanol, and stirred for 24 hours under the same conditions. The resulting reaction solution was dialyzed against water through a dialysis membrane (Spectra/Pro® MWCO; 1000) and lyophilized to give biotin-polyrotaxane conjugate.


[0111] After the reaction with biotin hydrazide, the resulting product was found to be water-soluble. It is known that hydrogen bond between the hydroxyl groups of α-CDs in polyrotaxanes exhibits limited water solubility. The reduction of the hydrogen bond by chemical modifications such as hydroxypropylation can significantly improve the water solubility of the polyrotaxane. The reduced hydrophilicity after introduction of biotin (hydrophilic ligand) appeared to be attributed to the association with alkyl chains in biotin. This was one of the.reasons to carry out the chemical modification of α-CDs with 2-aminoethanol (hydroxyethylcarbamoylation). As expected, the hydrophilicity of the polyrotaxane increased after the reaction.


[0112] The polyrotaxane conjugated with biotin hydrazide and 2-aminoethanol was analyzed by gel permeation chromatography and 1H-NMR spectroscopy. Gel permeation chromatography was performed using TSK gel G3000HHR+G5000HHR columns (available from Tosoh, Co., Tokyo, Japan) and elution in DMSO at flow rate of 0.8 mL/min, and detection was performed by determining angle of rotation in OR-990 (Japan Spectroscopic Co., Tokyo, Japan).


[0113] Yield: 34 mg. 1H-NMR (DMSO-d6, ppm): δ9.39(d, J=2.3 Hz, 2H×11, immobilized likage —OCOHN—NHCO—), 7.38-7.16 (brm, 10H×2, aromatic ring of Z-L-Phe), 7.15-6.80 (brm, 1H×104, immobilized linkage —OCONH— of hydroxyethyl carbamoyl group), 6.40, 6.34 (s, 2H×11, NH of biotin), 4.89 (brm, 6H×20, C1H, C6H2, C4H and C2H of α-CD), 3.51 (s, 4H×90, CH2CH2O of PEO), 3.04 (brm, 4H×104, CH2 of hydroxyethyl carbamoyl group), 2.82 (dd, J=4.5, 7.5 Hz 1H×11, CεH of biotin), 2.58 (d, J=12.8 Hz, 1H×11, CεH′ of biotin), 2.08 (m, 2H×11, CαH of biotin), 1.63-1.23 (m, 6H×11, CβH/CγH/CδH of biotin). The number of α-CDs and immobilized biotin were determined from the 750 MHz 1H-NMR spectrum.


[0114]
FIGS. 1A to 1E show the results of gel permeation chromatography: FIG. 1A for purified biotin-polyrotaxane conjugate; FIG. 1B for hydroxyethyl carbamoyl-polyrotaxane; FIG. 1C for biotin-α-CD conjugate (0.6 biotin per α-CD); FIG.. 1D for α-CD; and FIG. 1E for d-biotin. The peak attributed to the biotin-polyrotaxane conjugate was detected as a single peak within its elution time, which was significantly shorter than that of any of the biotin-α-CD conjugate, α-CD and d-biotin. Further, the elution time profile of the biotin-polyrotaxane conjugate was very close to that of hydroxyethylcarbamoyl-polyrotaxane. These results indicate that the product obtained was a polyrotaxane derivative with no contamination.


[0115] In order to confirm the chemical composition of the polyrotaxane derivative (i.e., biotin-polyrotaxane conjugate), its 1H-NMR spectrum was compared with those of biotin hydrazide and hydroxyethylcarbamoyl-polyrotaxane (FIG. 2A to 2C). FIGS. 2A, 2B and 2C show results for biotin-polyrotaxane conjugate, d-biotin, and hydroxyethylcarbamoyl-polyrotaxane, respectively. The peaks attributed to d-biotin and hydroxyethylcarbamoyl-polyrotaxane were confirmed in the analysis of biotin-polyrotaxane conjugate. The peak attributed to the hydrazide groups (δ=8.91 in FIG. 2B) exhibited a downfield shift (δ=9.39 in FIG. 2A). This peak shift shows that the d-biotin hydrazide was introduced to the hydroxyl groups of α-CDs in the polyrotaxane via carbamoyl linkages. These results indicate that the biotin was conjugated with polyrotaxane and the supramolecular structure of the latter was maintained after the biotin immobilization.


[0116] One polyrotaxane molecule contained 20 α-CDs, 11 biotins and 104 hydroxyethylcarbamoyl groups as determined based on the 1H-NMR spectra, indicating that about one biotin molecule was present for two α-CD molecules.


[0117] The conformation of the synthesized biotin-polyrotaxane conjugate in an aqueous solution was analyzed by two-dimensional nuclear Overhauser effect spectroscopy (2D NOESY). There were no correlated peaks between the peaks of d-biotin (NH, Cα-δH, CεH, CεH′, CζH, CζH′) and those of hydroxyethylcarbamoyl-polyrotaxane (aromatic ring of Z-L-Phe, O6H, C5H, C6H2, C4H, C3H, C2H and C1H of α-CD, CH2CH2O of PEO, and CH2 of hydroxyethylcarbamoyl group), although several correlated peaks were observed between the glucose units of α-CDs, presumably due to configurational changes after conjugation. These results indicate that the biotin molecules in tie conjugate were exposed to a water-soluble environment without associating with each other.



Example 2

[0118] Analysis of Biotin-Polyrotaxane Conjugate Binding to Streptavidin-Immobilized Surface Using Surface Plasmon Resonance Analyzer (SPR Analyzer)


[0119] SPR experiments were carried out using an IAsys device (IAsys Auto+, Affinity Sensors Cambridge Inc. UK) that can quantify a wide range of biomolecular interactions by a resonance mirror biosensor. The IAsys device temperature was set at 25° C. The resonant layer of biotin cuvette was washed with 40 μL of PBS/T and allow to settle for 10 min for equilibration. During this equilibration, streptavidin was dissolved in PBS/T to 1 mg/ml. The solution of streptavidin in PBS/T (20 μL) was added to the PBS/T in the cuvette and left to stand for 10 min to allow the streptavidin to deposit to the biotin-immobilized surface. After washing the cuvette with 50 μL of PBS/T three times, the cuvette was left to stand for 3 min to stabilize the base line. The density of the deposited streptavidin was determined from the sensorgram obtained based on the IAsys calibration curve. After equilibrating the streptavidin-deposited surface with 45 μL of PBS/T, the biotin conjugate dissolved in PBS/T (50 nM biotin in the conjugate) was added to PBS/T in the cuvette, and the binding was then monitored for 10 min. Next, the cuvette was washed with 50 μL of PBS/T, and monitored for additional 5 minutes to observe dissociation. Finally, 1M formic acid was added to the surface to disrupt the biotin-streptavidin binding, then the cuvette was washed with PBS/T three times. The same procedure was repeated but using various concentrations of the biotin-polyrotaxane conjugate. The resulting sensorgram was analyzed based on pseudo-first-order kinetics to obtain kinetic parameters.


[0120] As described above, streptavidin tetramer was deposited on the biotin-immobilized IAsys cuvette. The density of the deposited streptavidin was 2.5×10−5 nmol/mm2, which means that streptavidin tetramer was deposited on the surface at a density of 1 streptavidin molecule/64.2 nm2, and that the average distance between two adjacent streptavidin tetramer molecules on the surface was therefore approximately 8.0 nm. Based on the estimated size of streptavidin tetramer (5.5 nm), a schematic view of the streptavidin-deposited surface is shown in FIG. 3.


[0121] Since the depth of α-CD is 0.7 nm and the stoichiometric number of α-CDs in a PEO chain (Mn: 4,000) is 45, the theoretical length of the polyrotaxane rod can be estimated to be 32 nm. Considering the number of α-CD in the conjugate (approximately 20) and the density of the streptavidin deposited on the surface, the potential for interaction was between four streptavidin tetramers and one conjugate molecule (FIG. 3). Binding curves showing binding of the conjugate to the streptavidin-deposited surface are shown in FIG. 4. The concentration was calculated on a biotin basis. The response increased as the concentration of the conjugate injected to the streptavidin-deposited surface increased from 1 nM to 50 nM. However, such an increase in the response was not observed when a streptavidin surface overcoated with 1 mM biotin was used. These results indicate that the biotin in the conjugate was actually recognized by streptavidin.



Example 3

[0122] Effect of the Number of Biotin Molecule in the Conjugate on Binding/Dissociation Constant


[0123] The above-described experiments showed that biotin-polyrotaxane conjugate containing approximately 11 biotin molecules was recognized by streptavidin-deposited surface. It should be noted that streptavidin does not bind to polyrotaxane itself. Next, how the number of biotin contained in one conjugate molecule affects the binding/dissociation constant associated with the multivalency of the biotin-polyrotaxane conjugates was examined.


[0124] The number of biotin contained in one polyrotaxane molecule could be varied by changing the molar ratio between CDI-activated polyrotaxane and EZ-Link biotin hydrazide (Table 2).
2TABLE 2Synthesis of biotin conjugate for kinetics analysisNumberNumberMolarofofSampleRatio *2Number ofα-CD/molHEC/molTotalCode *1[Bio]/[Im]biotin/mol*3*3Mn11BIO-α/  0.5112010433,300E4-PHE-Z35BIO-α/1352211343,500E4-PHE-Z78BIO-α/2782218860,900E4-PHE-Z1BIO-α1 *4141,480


[0125] In Table 2, BIO-α/E4-PHE-Z and BIO-αCD represent biotin-polyrotaxane and biotin-α-CD conjugates, respectively (*1). In the first column in Table 2, information regarding the number of CDs per conjugate and the functional group(s) or ligand(s) linked thereto are provided before a (/) mark. For example, 11BIO-α/E4-PHE-Z means that the sample conjugate contains 11 biotins as functional groups and α-CDs as the cyclic molecule. Information regarding the linear molecule which is threaded through the cyclic molecules and the capping bulky substituents are provided after the (/) mark. For example, 11BIO-α/E4-PHE-Z means that the sample conjugate contains a polyethylene glycol (PEG) having an average molecular weight of 4,000 capped with benzyloxycarbonyl-L-phenylalanine (Z-PHE) groups at its both ends. [Bio] and [Im] refer to the concentrations of EZ-Link™ biotin hydrazide and N-acyl imidazole group (the activated hydroxyl group of α-CDs in the polyrotaxane), respectively (*2). The number of α-CD and of hydroxyethylcarbamoyl group (HEC) were calculated based on the 750 MHz 1H-NMR spectrum (*3). One N-acylimidazole group per α-CD has been introduced (*4).


[0126] The SPR sensorgram showing the binding/dissociation of 11BIO-α/E4-PHE-Z, 35BIO-α/E4-PHE-Z and 78BIO-α/E4-PHE-Z to and from the streptavidin-deposited surface is shown in FIG. 5. The concentration of biotin in the conjugate is 50 nM and the fine and rough dotted lines and the solid line represent reactions of 11BIO-α/E4-PHE-Z, 35BIO-α/E4-PHE-Z and 78BIO-α/E4-PHE-Z, respectively, in FIG. 5. Injection of each conjugate onto the streptavidin-deposited surface increased reaction though no qualitative difference was detected in the binding reaction depending on the difference in the number of biotin in the conjugate. In order to dissociate biotin-polyrotaxane conjugate, the solution was replaced by PBS/T buffer, and dissociation curves were obtained 4 minutes after injection (FIG. 5). It seemed that conjugate with larger number of biotin had a gentler slope in its the dissociation curve. These results suggest that the number of biotin affected the dissociation rather than the binding.


[0127] In order to dissect the binding/dissociation constant, the binding curves in FIG. 5 were analyzed in terms of the pseudo-first-order kinetics, which was based on the interaction between ligand (L: in this case biotin-polyrotaxane conjugate) and immobilized receptor (R: in this case streptavidin):
4


[0128] wherein kbind is a bindings constant, kdiss a dissociation constant, and Kα an association equilibrium constant. Rt (which represents an SPR response at time t) and dR/dt (the binding rate) can be used in the following kinetics of interaction:




dR/dt=k


bind


C


L
(Rmax−Rt)−kdissRt   (4a)





R


t


=R


eq
[1-exp (−kobst)]   (4b)





k


obs


=k


bind


C


L


+k


diss
  (4c)



[0129] wherein CL is the concentration of conjugate injected (in this case, the biotin bound), Rmax the maximum binding response and kobs the pseudo-linear rate of the binding. The kobs value was calculated for the conjugates from their binding curves obtained by changing the conjugate concentration. Plot of kobs as a function of biotin concentration in the conjugate [Eq. (4c)] was well fitted to a linear line (r2=0.987 to 0.998) using the linear least-square method. Thus, kbind and kdiss were calculated using Equation (4c). Table 3 summarizes the kinetic parameters for 11BIO-α/E4-PHE-Z, 35BIO-α/E4-PHE-Z and 78BIO-α/E4-PHE-Z.
3TABLE 3kbindkdisskaBinding(×104 M−1sec−1)(×10−3 sec−1)(×107 M)11BIO-α/E4-PHE-Z13.81.68.635BIO-α/E4-PHE-Z1.70.394.478BIO-α/E4-PHE-Z5.20.052100.0


[0130] These data show that the kdiss value dramatically decreased as the number of biotin in the conjugate increased while the value in the kbind remained about the same. Accordingly, the Ka value of 78BIO-α/E4-PHE-Z was about 12-fold higher than that of 11BIO-α/E4-PHE-Z and about 22-fold higher than that of 35BIO-α/E4-PHE-Z. It is known that high-affinity mediated by multivalent interaction is due to decrease in the dissociation rate of multivalent ligand, rather than to increase in the binding rate. Therefore, decreased in the kdiss value indicates that biotin (ligand) in the conjugates bind multivalently to the deposited streptavidin.


[0131] However, Winzor et al. suggested that the pseudo-first-order kinetics is not suitable for the analysis of multivalent interaction. Therefore, whether the dissociation constant follows the pseudo-first-order kinetics or not was examined.


[0132] To evaluate the dissociation constant, the classical expression was considered for the dissociation based on the pseudo-first-order kinetics. CL in Equations (4a) to (4c) should be zero for the dissociation process since the buffer containing the conjugates in the SPR cuvette was replaced by the buffer without conjugate. Thus, the dissociation constant can be expressed by the following equations:




R


t


·R


0
=exp (−kdisst)   (5a)





ln
(Rt/R0)=−kdisst   (5b)



[0133] where R0 is the degree of SPR response at the start point of the buffer injection. There should be a linear relationship between In (Rt/R0) and time if the dissociation constant follows Equation (5b). FIG. 6 shows time dependence of ln (Rt/R0) for 11BIO-α/E4-PHE-Z (▪ in FIG. 6), 35BIO-α/E4-PHE-Z (▴ in FIG. 6) and 78BIO-α/E4-PHE-Z (&Circlesolid; in FIG. 6). In FIG. 6, the fine dotted line, the rough dotted line and the solid line indicate theoretical linear lines for 11BIO-α/E4-PHE-Z, 35BIO-α/E4-PHE-Z and 78BIO-α/E4-PHE-Z, respectively, obtained using the corresponding kdiss values in Table 3. The experimental plots in FIG. 5, determined based on the text data of the SPR sensorgram, did not conform to the linear lines predicted by the logarithmic function of Equation (5b). All the conjugates (including those with larger number of biotin) had gentle slopes in the carves after 0.6-0.8 min. These results suggest that the biotin-polyrotaxane conjugates may re-bind with the streptavidin-deposited surface, which strongly supports their multivalent property. The linear lines without any marks ▪, ▴ or &Circlesolid; in FIG. 6 represent the theoretical relationship obtained by applying the kdiss values in Table 3 to Equation (5b). These lines did not conform to the experimental plots. However, the slopes of the linear lines seem to substantially conform to those of the experimental plots after the re-binding, which shows that the calculated kdiss values in Table 3 may represent the multivalent kinetics.



Example 4

[0134] Competitive Inhibition of Streptavidin-Biotin Binding by the Multivalent Inhibitor (Biotin-Polyrotaxane) and the Monovalent Inhibitor (Biotin-α-CD)


[0135] In order to compare the kinetics of the biotin-polyrotaxane conjugates with that of the biotin-α-CD conjugate, firstly, binding of biotin-α-CD conjugate (1BIO-αCD in Table 2) to the streptavidin-deposited surface was analyzed by SPR. Unfortunately, significant SPR sensorgram could not be obtained for 1BIO-αCD due to its low molecular weight. According to the current SPR technology, it is difficult to detect the interaction between a low-molecular-weight ligand (Mn<˜5000) and its immobilized receptor since the size of the molecule formed on the sensor surface by complexing of such a small ligand with the receptor is too small to change the refractive index. As an alternative, we carried out a competitive inhibition assay for quantifying the substance that inhibits the interactions between a soluble receptor and its immobilized ligand (see, Mammen, et al., Angew. Chem. Int. Ed. 37 (1998) 2754-2794; Mann et al., J. Am. Chem. Soc. 120 (1998) 10575-10582; Sigal et al., J. Am. Chem. Soc. 118 (1996) 3789-3800).


[0136] Competitive Assay


[0137] Competitive assay was performed using biotin-polyrotaxane and biotin-α-CD conjugate according to the method reported by Kiessling et al. The biotin-polyrotaxane or the biotin-α-CD conjugate (which corresponds to 78BIO-α/E4-PHE-Z or 1BIO-αCD in Table 2, respectively) was dissolved in PBS/T to a biotin concentration of 1 mM, and the other 5 dilution samples of 0.25, 0.5, 1.0, 10 and 100 μM were additionally prepared.


[0138] One hundred micro liters of solution of streptavidin in PBS/T (0.1 mg/ml, 1.5 μM) was added to each sample solution (0.9 ml) and mixed well using a mixer. These solutions were incubated for 1 hour at room temperature. Each of the resulting solutions (5 μL) were injected to the resonant layer of a biotin cuvette that was equilibrated with 45 μL of PBS/T (10 times dilution of the sample solution). The SPR reaction was monitored in the same manner as in the binding analysis using the biotin cuvette. To obtain the inhibition constant (Ki), the SPR data were analyzed by solution competition equation using a modified rectangular hyperbolic relationship:




f=[I
]/([I]+Ki(1+F/Kd))   (6)



[0139] where f is fractional inhibition that is calculated using equilibrium values obtained in the absence of inhibitor (biotin conjugate), [I] the concentration of inhibitor (biotin residue), F the concentration of free binding sites available for the streptavidin, and Kd the dissociation constant of streptavidin from the surface. To determine the F and Kd values, data on the binding of streptavidin to the surface of the biotin cuvette (final streptavidin concentrations in the cuvette: 0.1 to 10 μg/ml) were collected, and its response values were fitted to the following rectangular hyperbolic equation:




R


eq


=R


max


[SV
]/(Kd+[SV]), Kd=Rmax/2   (7)



[0140] where Req is equilibrium response, Rmax the maximum binding response of the streptavidin, and [SV] the concentration of streptavidin. The F and Kd values calculated were found to be 7.9±0.46 nM and 3.2±0.92 nM, respectively. The Ki values for 78BIO-α/E4-PHE-Z and 1BIO-αCD were derived by a curve fitting the obtained plots of f and [I] based on Equation (6) using Microcal Origin 6.0 software.


[0141] Concentration-dependent inhibition curves obtained by measuring the binding of 0.015 μM streptavidin to the surface in the presence of various concentrations of the biotin-polyrotaxane conjugates or biotin-α-CD (1BIO-αCD) conjugate are shown in FIGS. 7A and 7B. Particularly, FIGS. 7A and 7B show inhibition curves illustrating the inhibition of 0.015 μM streptavidin binding to a biotin-immobilized sensor surface by biotin in 0, 0.025, 0.05, 0.1, 1 and 10 μM conjugates. FIG. 7A shows inhibition by 78BIO-α/E4-PHE-Z while FIG. 7B shows inhibition by 1BIO-αCD. The Req value was 1,000 to 1,200 arc/second in the absence of conjugate and decreased as the concentration of conjugates increased (from 0 to 10 μM as biotin basis) for the both conjugates. Within lower concentration range (0.025-0.1 μM), the Req value for 78BIO-α/E4-PHE-Z was relatively smaller than that for 1BIO-αCD, suggesting that the binding ability of 78BIO-α/E4-PHE-Z to streptavidin in solution was superior to that of 1BIO-αCD.


[0142] The inhibition constant Ki value indicating inhibition of streptavidin binding to the biotin-immobilized surface by conjugate was calculated by using the plot of fractional inhibition vs. the conjugate concentration (FIG. 8) and Equation (6). In, FIG. 8, &Circlesolid; and ▴ indicate the results for 78BIO-α/E4-PHE-Z and 1BIO-αCD, respectively. The Ki values for 78BIO-α/E4-PHE-Z and 1BIO-αCD were 2.13±0.25 and 9.48±1.08 nM, respectively. These results suggest that the biotin-polyrotaxane conjugate had from 4- to 5-fold higher activity than that of the biotin-α-CD conjugate.


[0143] Streptavidin is known to form tetramer that has four binding sites, and its size is assumed to be 5.5 nm. It can be assumed that the depth of α-CD is 0.7 nm and the stoichiometric number of α-CDs which can be threaded onto one PEO chain (Mn: 4,000) is approximately 45. The theoretical length of polyrotaxane rod may therefore be 32 nm. Since one 78BIO-α/E4-PHE-Z molecule contains approximately 22 α-CDs, it can be assumed that the majority of the biotin-polyrotaxane conjugate can span two of the binding sites of streptavidin, thereby noncovalent cross-linking streptavidin (FIG. 9A). On the other hand, 1BIO-αCD cannot span any binding sites (FIG. 9B). Therefore, it can be considered that the enhanced inhibitory activity of the biotin-polyrotaxane conjugate may be attributed to its linear structure in which multiple biotin-conjugated α-CDs are bound to the PEO chain (polyrotaxane backbone) so that the biotin-conjugated α-CDs are arranged in a line along the PEE chain.



Example 5

[0144] Synthesis and Characterization of Carboxyethylester Polyrotaxane (a Novel Calcium Chelating Polymer)


[0145] Polyrotaxane was allowed to react with succinic anhydride in pyridine to introduce carboxyethylester group into the polyrotaxane via reaction between the hydroxyl group of the polyrotaxane and the succinic anhydride. This reaction was selected because the nucleophilic reaction using anhydride is known to maintain the structure of polyrotaxane (Watanabe et al., J. Biomater. Sci. Polym. Edn. 10 (1999) 1275-1288).


[0146] Particularly, carboxyethylester-polyrotaxane was synthesized according to a modified version of the method described in Tanaka et a., J. Antibiotics, 47 (1994) 1025-1029. Synthesis of caxboxyethylester-polyrotaxane (132CEE-α/E4-PHE-Z) is shown below:
5


[0147] In Structural Example 3 above, polyrotaxane comprising a PEO-BA chain, multiple α-CDs threaded onto the PEO-BA chain capped with Z-L-Phe groups was synthesized in the same way as the procedure described above for the biotin-conjugated polyrotaxane. The polyrotaxane obtained (which contained 30 α-CDs as determined by 1H-NMR assay) (6.03×10−6 mole) and succinic anhydride (3.26×10−6 mole) (available from Wako Pare Chemical Co. Ltd.) were dissolved in pyridine anhydride and stirred at room temperature a The reaction mixture was washed three times with an excess amount of ether. Precipitate was collected by centrifugation and dried under reduced pressure to give carboxyethylester-polyrotaxane (CEE-α/E4-PHE-Zs). CEE-α-CD was synthesized in the same manner as CEE-polyrotaxane.


[0148] From the 1H-NMR spectrum of the recovered sample, all the peaks were identified to be attributed to α-CDs, PEG-terminal group and carboxyethyl carbonyl group (FIG. 10). Further, a single peak was detected for 132CEE-α/E4-PHE-Z, and its elution time was much shorter than that of 6CEE-α-CD as determined by gel permeation chromatography (GPC) analysis (FIG. 11). These results indicate that the structure of polyrotaxane was maintained after the chemical modification. Table 4 shows the results of synthesis. The Mn of the PEG in CEE-α/E4-PHE-Zs is 4000 (*1). The molar ratio between succinic anhydride and α-CD is 1.0 (*2). The number of CEE group was determined based on the 1H-NMR spectrum (*3)
4TABLE 4The number ofThe number ofThe numberSampleReactionα-CD/CEEof CEECodetimepolyrotaxanegroup/α-CDgroup/PRX*1(hour) *2*2*3*333CEE-α/222233E4-PHE-Z68CEE-α/622368E4-PHE-Z132CEE-α/24226132 E4-PHE-Z6CEE-α/16CD


[0149] As shown in Table 4, the number of CEE group can be controlled by changing the reaction time. The molar ratio between the hydroxyl group of α-CDs in the polyrotaxane and succinic anhydride had no effect on the number of CEE group. The maximum number of CEE group incorporated was 132, indicating that CEE groups were introduced to all the primary hydroxyl groups of α-CDs in the polyrotaxane. All the primary hydroxyl groups of α-CDs in 6CEE-α-CD were also modified (Table 2).


[0150] The degree of substitution with CEE group was estimated from the ratio of the peak for methylene group of the CEE group (2.28 ppm) to C(1)H (4.88 ppm) of α-CD on the 1H-NMR spectrum.


[0151] CEE-Polyrotaxane


[0152]

1
H-NMR (D2O+NaOD, ppm): δ7.35-7.18 (aromatic ring of Z-L-Phenylalanine), 4.88 (C(1)H of α-CD), 4.00-3.30 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD), 3.58 (methyl group of PEO), 2.28 (methyl group of CEE), CEE-α-CD 1H-NMR (D2O+NaOD, ppm): δ4.88 (C(1)H of α-CD), 4.00-3.30 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD), 3.58 (methyl group of PEO), 2.50-2.00 (methyl group of CEE)


[0153] Next, the effects of the supramolecular structure of polyrotaxane on its solubility at various pH conditions, calcium chelating ability and trypsin inhibition were determined using 132CEE-α/E4-PHE-Z and 6CEE-α-CD.



Example 6


Solubility in a Buffer at Various pH Conditions

[0154] The solubility of 132CEE-α/E4-PHE-Z and 6 CEE-α-CD (Table 1) in PBS was determined at various pH conditions by phenol-sulfuric acid method. An excess amount of 132CEE-α/E4-PHE-Z or 6CEE-α-CD was suspended in a 0.5M phosphate buffered saline (PBS). The pH was adjusted by adding 5M NaOH solution. Phenol-sulfuric acid method was performed according to the previous method (Watanabe et al., Chem. Lett(1998) 1031-1032). Based on the glucose (monosaccharide) content quantified by phenol-sulfuric acid method, the concentration of 132CEE-α/E4-PHE-Z and the number of α-CDs per polyrotaxane were calculated.


[0155]
FIG. 12 shows the solubility of 132CEE-α/E4-PHE-Z (&Circlesolid;) and 6CEE-αCD (▴) in PBS at various pH conditions. The solubility of 132CEE-α/E4-PHE-Z and 6CEE-α-CD increased at up to pH4 due to the ionization of carboxyl groups. The solubility of 132CEE-α/E4-PHE-Z substantially remained at a constant level between pH4 and pH8 and then slowly decreased until pH11. Neutralization by sodium ion would explain this decrease. Since the sodium hydroxide solution was added to the mixture in order to adjust the pH of the solution of 132CEE-α/E4-PHE-Z, the concentration of sodium ion and pH increased. It can be assumed that the neutralization of carboxyl group by the sodium ion reduced the hydration of 132CEE-α/E4-PHE-Z. The effect of such neutralization has been reported on carbopol (Unlu et al., Pharm. Acta. Helv., 67 (1992) 5-10). Unlike 132CEE-α/E4-PHE-Z case, the solubility of 6CEE-α-CD decreased from pH5. Since a smaller peak was detected for CEE group on the NMR spectrum, it can be assumed that the solubility of 6CEE-α-CD was decreased from pH5 because the group were included into the cavity of α-CD and formed a complex with the α-CD. The solubility of 132CEE-α/E4-PHE-Z was lower than that of 6CEE-α-CD, indicating that hydrogen bond between unmodified hydroxyl groups (secondary hydroxyl group) in 132 CEE-α/E4-PHE-Z reduced the solubility. The ester bond of these CEEs was found to be stable at pH6-8 for 2 months or more.



Example 7

[0156] Polyacrylic acid (PAA, Mw=25000) and calcium chloride were purchased from Wako Pure Chemical Co. Ltd. 2-N-morpholinoethanesulfonic acid (MES) was purchased from Nacalai Tesque, Inc. (Osaka Japan).


[0157] Calcium Binding Assay


[0158] Calcium binding assay was performed to examine the effect of the polyrotaxane structure on calcium ion chelating 132CEE-α/E4-PHE-Z (0-1.29×10−4 mole) or 6CEE-α-CD (0-3.23×10−4 mole) was dissolved in an aqueous solution of 59 mM 2-N-morpholinoethane sulfonic acid (MES) adjusted to pH6.7 with 1M potassium hydroxide containing 13 mM calcium chloride (MES/KOH buffer, pH6.7), and stirred at room temperature for 2 hours. The concentration of free Ca2+ ion ([Ca2+]free) was determined using a calcium ion-sensitive electrode (HORIBA, Ltd., Japan). The concentration of chelated calcium ion ([Ca2+]bind) was calculated using the following equation:


[Ca2+]bind=[Ca2+]total−[Ca2+]free


[0159] where ([Ca2+]total) is the total concentration of Ca2+.


[0160] The deleted calcium ion ([Ca2+]bind) bound to 132CEE-α/E4-PHE-Z (&Circlesolid;), polyacrylic acid (PPA) (▪) or 6CEE-α-CD (▴) is shown as a function of the ratio of CEE concentration to total calcium ion concentration ([CEE]/[Ca2+]total) in FIG. 13. [Ca2+]bind of PAA increased in proportion to [CEE]/[Ca2+]total by the value around 2-3, and then slowly increased as [CEE]/[Ca2+]total increased. This result was consistent with the previous report by Kriwet and Kissel, Int. J. Pharm. 127 (1996) 135-145.


[0161] The 132CEE-α/E4-PHE-Z chelated calcium ion up to 90% as [CEE]/[Ca2+]total increased, indicating that calcium ion chelating capacity of 132CEE-α/E4-PHP-Z is equal to or slightly lower than that of PAA. On the other hand, the maximum [Ca2+]bind of 6CEE-α-CD was approximately 40%, Presumably, both or either of the above-described inclusion of CEE group into the cavity of α-CD (where the CEE group forms a complex with the α-CD) and the small number of CEE per one molecule may reduce the binding capacity. Thus, calcium chelating may be enhanced by the supramolecular structure of the polyrotaxane in relation to increase in the concentration of CEE group.



Example 8

[0162] Trypsin (CE 3.4.21.4.4 type IX, derived from pig spleen), N-α-benzoyl-L-arginine ethylester (BAEE) and N-α-benzoyl-L-arginine (BA) were purchased from Sigma (St. Lois, Mo., U.S.). Other compounds were of the highest-purity.


[0163] Trypsin Inhibition Assay


[0164] There are two hypotheses which explain the mechanism of trypsin inhibition by polyacrylic acid (PAA): one is calcium ion chelation (Luessen et al., Pharm. Res. 12 (1995) 1293-1298; Luessen et al., Eur. J. Pharm. Sci. 4 (1996) 117-1285; Lussen et al., J. Control. Rel. 45 (1997) 15-23); and the other is its direct interaction with the enzyme (Walker et al., Pharm. Res. 16 (1999) 1074-1080). In order to evaluate the effect that 132CEE-α/E4-PHE-Z may have on the inhibition of trypsin activity, trypsin inhibition assay was performed to examine digestion of N-α-benzoyl-L-arginine ethylester (BAEE) by trypsin in the presence of 132CEE-α/E4-PHE-Z, PAA and 6CEE-α-CD.


[0165] The following samples were dissolved in MES/KOH buffer (pH6.7) for use in trypsin inhibition assay.


[0166] a) 0.18% (w/v) PAA


[0167] b) 0.75 (w/v) 132CEE-α/E4-PHE-Z


[0168] c) 0.66% 6CEE-α-CD


[0169] In the assay, 25 mM carboxyl group was used. MES/KOH buffer was used as a control.


[0170] N-α-benzoyl-L-arginine ethylester (1.5 mmol) was dissolved in each of the sample solutions. Various dilutions of the substrate solutions (5 ml each) were used in the degradation assay. Degradation experiments were started by adding trypsin (final concentration=24.0 IU/ml) to each sample at 37° C. In order to analyze the degradation using high performance liquid chromatography (HPLC), the reaction solution (50 ul) was sampled at appropriate time points and diluted in 1 ml of phosphoric acid (pH2) to stop trypsin activity. The degradation product (N-α-benzoyl-L-arginine, BA) was analyzed by the H-PLC using a reversed-phase column (COSMOSIL 5C18-AR-II, 250×4.5 mm; Nacalai Tesque, Inc., Kyoto, Japan) at a flow rate of 0.75 ml/min. The mobile phase consisted of: eluate A, 86% (v/v) 10 mM ammonium acetate (pH4.2) and 14% (v/v) acetonitrile; and eluate B, 80% (v/v) 10 mM ammonium acetate (pH4.2) and 20% (v/v) acetonitrile. Gradient elution was performed as follows: 0-8 min: 92% A/8% B, isocratic; 8-10 min: 50% A/50% B, linear gradient; 10-13 min: 50% A/50% B, isocratic. BA was detected at 253 nm. Under these conditions, the elution peak of BA was detected at 6.351 min.


[0171] The degree of trypsin inhibition was expressed by an inhibition factor (IF) (Madsen et al., Biomaterials 20 (1999) 1701-1708) as follows:




IF=AUC


control


/AUC


polymer




[0172] where AUC is the area under BA vs. time curve in the absence (AUCcontrol) or presence (AUCpolymer) of polymers.


[0173]
FIG. 14 shows the effect of conjugates on trypsin activity in the presence or absence of calcium chloride (20 mg/ml). In this experiment, an excess amount of calcium chloride was added just before trypsin reaction to evaluate the effect of calcium ion chelation on trypsin inhibition. In the absence of calcium chloride, the hydrolyzed N-α-benzoyl-L-arginine ethylester (N-α-benzoyl-arginine, BA) increased with time (6CEE-α-CD>>132CEE-α/E4-PHE-Z>PAA). That seems to be an inverse relationship between the amount of hydrolyzed N-α-BA and the calcium chelating ability.


[0174] When an excess amount of calcium chloride was added before the degradation, the amount of N-α-benzoyl-arginine (BA) increased over 60 minutes in the presence of 132CEE-α/E4-PHE-Z or PAA when compared with the case without addition of excess calcium chloride, but not in the presence of 6CEE-α-CD. These results suggest that calcium chelation by 132CEE-α/E4-PHE-Z and PAA correlates to trypsin inhibition.


[0175] To quantitatively determine the inhibitory effect, inhibition factors (IFs) of the 132CEE-α/E4-PHE-Z, PAA and 6CEE-α-CD during the 60 minute-reaction were calculated (FIG. 15). In FIG. 15, * shows that there is a significant difference in the inhibition factors in t-test (P<0.05). The IF values of 132CEE-α/E4-PHE-Z and PAA significantly decreased by addition of an excess amount of calcium chloride while that of 6CEE-α-CD did not change. Similar results were obtained in a 180 minute-reaction.


[0176] In the presence of an excess amount of calcium chloride, 132CEE-α/E4-PHE-Z was suspended in the solution while PAA precipitated in the solution. The precipitation of PAA suggests that all the carboxyl groups in PAA were stoichiometrically involved in calcium chelation (Kriwet, Kissel, 1996) and that the PAA content in the solution decreased. On the other hand, the suspension of 132CEE-α/E4-PHE-Z indicates that there existed CEEs that did not involved in calcium chelation in the solution. This may be supported by the observation that less calcium chelation took place in the 132CEE-α/E4-PHE-Z suspension than in PAA solution (FIG. 13). PAA is considered to bind directly to and thus reduce the activity of trypsin (Walker et al, Pharm. Res. 16 (1999) 1074-1080). Therefore, under the co-presence of an excess amount of calcium chloride and PAA, if all the PAA has been dissolved in the solution in the presence of an excess amount of calcium ion, the IF value will increase. Therefore, the mechanism of trypsin inhibition by 132CEE-α/E4-PHE-Z may be attributed to its relatively weak calcium. chelating ability. It can be assumed that the trypsin inhibition by 6CEE-α-CD may be mediated by another mechanism. Presumably, the inhibition mechanism may involve reducing the accessibility of trypsin to N-α-benzoyl-L-arginine ethylester (BAEE) by including the aromatic groups of the N-α-benzoyl-L-arginine ethylester (BAEE) and/or trypsin into the cavity of 6CEE-α-CD (Rekharsky et al., Chem. Rev. 98 (1998) 1875-1917).


[0177] The above-described trypsin inhibition experiments showed that trypsin inhibition by carboxyethylester-polyrotaxane was due to calcium chelating rather than to non-specific interaction. Owing to this property, the inventive multivalently interactive molecular assembly can be used as a calcium chelating agent to inhibit, for example, trypsin, or to open the tight junction of small intestine, as well as for other biological effects of calcium chelating.



Example 9

[0178] Inhibition of Trypsin Activity by Various Carboxyethylester-Conjugated Polyrotaxanes Comprising PEG of Different Molecular Weight with Different Number of Threading α-CD


[0179] The above Examples showed that the inhibition of enzyme activity by CEE-polyrotaxane may depend on calcium chelation rather than non-specific interaction. In this Example, trypsin inhibition activity was determined using various CEE-polyrotaxanes comprising PEG of different molecular weight with different number of threading α-CDs to examine the inhibition of enzyme activity by the CEE-polyrotaxanes and the calcium-dependency of enzyme activity inhibition.


[0180] First, carboxyethylester-polyrotaxanes were synthesized. Here, polyrotaxanes having capping benzyloxy carbonyl-L-tyrosine (Z-L-Tyr) groups at the both ends thereof (MW of PEG: 2000 or 4000) were used. Each of the polyrotaxanes (6.03×10−6 mol) was stirred heterogeneously in pyridine (solvent) with succinic anhydride (3.26×10−6 mol). Next, the mixture was precipitated again and washed in a large amount of ether. The resulting precipitate was collected by centrifugation and dried under reduced pressure to give carboxyethylester-polyrotaxane (CEE-polyrotaxane). The amount of α-CDs threaded onto the PEG chain and CEEs introduced were counted by a 1H-NMR assay. The results are shown in Table 5 below.
5TABLE 5Synthesis of CEE-polyrotaxaneMn of# of CEE/# of α-CDs/% ofSample codeaPEGmolebmolebthreadingb132CEE-α22/E4-TYR-Z4,0001322249132CEE-α22/E2-TYR-Z2,0001322210096CEE-α16/E2-TYR-Z2,00096167266CEE-α11/E2-TYR-Z2,000661150aCEE-α/E-TYR-Z: carboxyethylester-polyrotaxane bCalculate from the 1H-NMR spectra.


[0181] PEGs of MW4,000 and 2,000 were used to synthesize 132CEE-α22/E4-TYR-Z and 132CEE-α22/E2-TYR-Z (Table 5) both containing the same number of α-CDs and CEE group, and the ability of these compounds to inhibit trypsin activity was evaluated.


[0182] The ability of CEE-polyrotaxanes to inhibit trypsin activity was evaluated as described below.


[0183] A model substrate N-α-benzoyl-L-arginine ethylester (BAEE) (1.5 mM) and each CEE-polyrotaxane were dissolved in 2-(N-morpholino) ethane sulfonic acid (MES) buffer (MES/KOH, pH6.7). Next, the solution was stirred in a thermostat at 37° C. under a constant temperature condition, and added with trypsin (24.0 IU/mL) to start enzymatic degradation. After that, 50 μL of sample was collected at different time points and added to 1 mL of phosphoric acid (pH2) to quench the reaction. Then, the degraded product N-benzoyl-L-arginine (BA) was quantified by high performance liquid chromatography (HPLC). The amount of carboxyl group of the CEE-polyrotaxane in the solution was kept the same.


[0184] HPLC was performed using the following conditions. Column: COSMOSIL 5C18-AR-II (Nacalai Tesque, Inc.); column temperature=37° C.; flow rate=0.75 mL/min; detection by UV (253 nm); developer A=ammonium acetate buffer 86% (v/v)+acetonitrile 14% (v/v), and developer B=ammonium acetate buffer 50% (v/v)+acetonitrile 50% (v/v); gradient=0-8 min A:B=92:8 (isocratic), 6-18 min A:B=50:50 (linear gradient), 10-13 min A:B=50:50 (isocratic).


[0185] The results are shown in FIG. 16. The ability of 132CEE-α22/E2-TYR-Z (comprising PEG2,000 as the linear molecule) to inhibit enzyme (trypsin) activity was higher than not only that of 132CEE-α22/E4-TYR-Z (comprising PEG4,000 as the linear molecule) but also that of PAA, indicating that high carboxyl density due to high α-CD density rather than to the number of CEE may be important for inhibition of trypsin activity.


[0186] In order to examine the effect of the number of α-CDs on the inhibition of trypsin activity, CEE-polyrotaxanes comprising PEG-2,000 as the linear molecule with different threading ratio of α-CD (from 100% to 50%) (see Table 5) were used to assay their trypsin inhibition activity. Trypsin inhibition activity is expressed by an IF value.




IF=AUC


control


/AUC


polymer




[0187] AUC represents the area under the time vs. BA concentration curve: AUCcontrol the area under the time vs. BA curve obtained using substrate and enzyme alone, and AUCpolymer the area under the time vs. BA curve obtained using substrate, enzyme and CEE-polyrotaxane. Greater IF value indicates higher inhibitory effect.


[0188] The results are shown in FIG. 17, which shows that higher inhibitory effect can be obtained as the number of CEE and α-CDs increase. Additionally, the effect of addition of an excess amount of calcium was determined to dissect the mechanism of enzyme activity inhibition. The inhibitory effect decreased drastically in 132CEE-α22/E2-TYR-Z case (with greater threading ratio of α-CD) after addition of an excess amount of calcium, which also suggests that the mechanism of enzyme inhibition by 132CEE-α22/E2-TYR-Z may depend on calcium chelation.



Example 10

[0189] Effect of Numbers of Carboxy Groups and Threaded α-CDs Within Polyrotaxane, on the Physical Interaction to Trypsine


[0190] An affect of a concentration of carboxyl groups and a ratio of threaded α-CDs within a polyrotaxane, to a physical interaction between a trypsin and the polyrotaxane was evaluated with a formation of a precipitation in a solution containing the trypsin and the polyrotaxane under the condition of high concentration of trypsin. With an increase in the number of α-CDs, as seen from FIG. 18A, an apparent velocity of a precipitation-formation was increased and a transmissivity of the suspension (the solution) was decreased. When to the suspension was added excessively Ca2+, as seen from FIG. 18B, a transmissivity of the suspension was largely increased and an apparent velocity of the transmissivity-increase was in proportion to the number of CEE-α-CD.


[0191] Here, in FIGS. 18A and 18B, a continuous line denotes the result of 66CEE-α11/E2-TYR-Z, a chain line denotes the result of 96CEE-α16/E2-TYR-Z, and a dotted line denotes the result of 132CEE-α22/E2-TYR-Z. As the similar tendency was shown with polylysine of polycation, it was suggested that this formation of a precipitation was occurred due to a polyioncomplex. Moreover, it was also suggested that a trypsin and a polyioncomplex were not dissociated even under the condition of high concentration of salt, and CEE-polyrotaxane inhibited a trypsin activity by a steric inhibition, so that an effect of trypsin activity was still exhibited with a small number of α-CDs under the existence of the excess amount of Ca2+. On the contrary, with regard to an increase in the number of CEE-α-CDs within the CEE-polyrotaxane, it was suggested that it was effective on an electrostatic interaction to bivalent cation, and the electrostatic interaction was induced a dissociation of the polyioncomplex to the trypsin.


[0192] As has been seen in above, a difference in a number of CEE-α-CD within CEE-polyrotaxane affects on a formation of a polyioncomplex. Moreover, a preferable trypsin inhibition which utilizes an electrostatic interaction to bivalent cation, can be exhibited with a increase in the number of a number of CEE-α-CD within CEE-polyrotaxane.



Example 11

[0193] Evaluation of Multivalent Interaction by Maltose-Polyrotaxane Conjugate


[0194] Multivalent interaction was evaluated using maltose-polyrotaxane conjugate.


[0195] At first, maltose-polyrotaxane conjugates were synthesized as described below.


[0196] Condensation reaction between the carboxyl group of the polyrotaxane in which the hydroxyl groups in α-CDs have been carboxyetlylesterified (CEE-PRX) and mono-aminated maltose (β-maltosylamine) was performed using BOP reagent to produce maltose (Mal)-polyrotaxane conjugates, Those were then purified by dialysis. Similarly, Mal-polyacrylic acid (Mal-PAA) was synthesized as the reference sample. The number of both threading α-CD and Mal introduced were determined by 1H-NMR. Results are shown in Table 6.
6TABLE 6Synthesis of Mal-polyrotaxanes# of α-CD(theor. #)# ofMn ofThreadingmal-TotalSample codeaPEGpercentbtosebMnb 88Mal-α22/E2-TYR 2,000 22 (22) 100%8867,000 120Mal-α30/E4-TYR 4,000 30 (45) 67%12093,000 340Mal-α68/E10-TYR10,000 68 (110) 62%340234,000 510Mal-α130/E20-TYR20,000130 (225) 58%510400,000 830Mal-α290/E35-TYR35,000290 (385) 75%830776,0001260Mal-α420/E50-TYR50,000420 (550) 78%1260995,000 78-PAA257852,000aMal-α/E-TYR-Z: Maltose-polyrotaxane conjugate bCalculate from the 1H-NMR spectra.


[0197] Next, hemagglutination inhibition test was performed to evaluate the interaction between Mal-polyrotaxane conjugate and concanavalin A (ConA), then 20 μL of diluted Mal-polyrotaxane conjugate in saline and 20 μL of solution of ConA in saline were dispensed in a 96well plate (U-bottom), stirred, and then incubated at 37° C. for 30 minutes. Next, 40 μL of 2% (v/v) rat erytlirocyte was added to the plate, and the mixture was stirred and then incubated at 37° C. for 30 minutes. The precipitation of erythrocyte was monitored to determine hemagglutination, and the minimum concentration to inhibit hemagglutination was determined. The ConA concentration was set up at a 4-fold higher value than the minimum concentration of ConA at which hemagglutination occurs.


[0198] The effect of hemagglutination inhibition by various Mal-polyrotaxane conjugates are shown in FIG. 19. Mal inhibited hemagglutination at 9.1×10−3M while Mal-polyrotaxane conjugate from 4.0×10−4M to 5.1×10−5M or more. It can be seen from these results that Mal-polyrotaxane conjugate exhibited from 23- to 180-fold higher inhibition than Mal. This result suggests multivalent interaction between Mal and ConA in relation to the polyrotaxane structure. Moreover, 510Mal-α130/E20-TYR-Z exhibited the highest inhibition, indicating that the supramolecular structure of the polyrotaxane is involved in the multivalent interaction.


[0199] The relationship between the inhibitory effect and the threading ratio of α-CD is shown in FIG. 20. Inhibitory effect was evaluated using the Relative MIC as shown in the following expression.


Relative MIC=(Min. inhibitory conc. of maltose)/(Min inhibitory conc. of maltose in the conjugate)


[0200] The results showed that higher relative MIC was obtained with lower threading ratio of α-CD while lower relative MIC with higher threading ratio of α-CD This is likely to be because, in a polyrotaxane with high threading ratio of α-CD, the high density of α-CDs or Mals causes steric hindrance between ConA and Mal, which may lead to lesser interaction. In a polyrotaxane with smaller number of threading α-CD, individual α-CD nay have relatively higher degree of freedom that may cause less steric hindrance, thereby allowing for efficient binding of Mal to the binding sites of ConA.


[0201] According to the present invention, a multivalently interactive molecular assembly which can effectively and stably bind to a target substance in vivo or in vitro, a capturing agent comprising said multivalently interactive molecular assembly for capturing an object of interest in vivo or in vitro, a drug carrier that aids administration of a drug, a calcium chelating agent that can effectively chelate calcium, and a drug enhancer that can be administered with a drug to assist in, for example, absorption of the drug can be provided.



Example 12

[0202] Here, we investigate how α-CDs and ligand mobility in ligandpolyrotaxane conjugates affect the multivalent interaction with a binding protein. Maltose and concanavalin A (Con A) were selected as a ligand and a binding protein, respectively, because Con A recognizes maltose and Con A-glycopolymer systems have been extensively studied as a model of multivalent interaction. A series of maltose-polyrotaxane conjugates (Mal-R/E20-TYR-Zs, 1-3) (FIG. 21) were synthesized by a condensation reaction between β-maltosylamine and carboxyethylester-polyrotaxanes in the presence of BOP reagent and HOBt. Because the stoichiometric number is ca. 227, the threading % values of α-CDs were 22%, 38%, and 53%, respectively (Table 7). As a reference, maltose-α-CD (Mal-α-CD, 4) and maltose-poly (acrylic acid) (Mal-PAA, 5) conjugates with a varying number of maltose groups were synthesized (Table 7).
7TABLE 7Synthesis of Maltose-Polyrotaxane Conjugates and theReference Samplessampleno. ofα-CDtotal no.no. ofcodeaα-CDbthreading (%)cof MalbMal/α-CDd1a5022400.81b601.21c1402.81d2304.62a8538440.52b580.72c1221.42d2442.93a12053420.43b640.53c1171.03d2402.04 33.05a425b555c1175d240aMn of PEG for 1-3, 20 000; Mn of poly(acrylic acid) for 5, 25 000. bCalculated from 1H NMR spectra. cCalculated by the ratio of the found and stoichiometric numbers of α-CD. If α-CDs are thread stoichiometrically onto a PEG chain, two ethylene glycol units should be included in ach α-CD cavity. α-CD threading (%) = [no. of α-CD]/[stoichiometric no. of R-CD] × 100 (see ref 3a). dNumber of Mal/α-CD was calculated from the integral ratio of the C(1)H and C(1′) of maltose and C(1)H of α-CD on 1H NMR spectra.


[0203] Synthesis of Maltose-Polyrotaxane Conjugates (1-3)


[0204] a) Preparation of Polypseudorotaxanes


[0205] Polypseudorotaxanes (inclusion complex of α-CDs and α,ω-diamino-PEG, Mn: 20,000) were prepared according to the previously reported by Harada et al. The number of α-CD threading was calculated from 1H-NMR spectra, comparing the integrations of the signals at 4.8 ppm (C(1)H of α-CD) with those at 3.5 ppm (CH2 of PEG).


[0206] b) Synthesis of Z-L-Tyr-Terminated Polyrotaxanes


[0207] Benzyloxycarbonyl-L-tyrosine (Z-L-Tyr) (3.9 g, 0.124 mmol), benzotriazol-1-yloxytris(dimethylamino)phosphomium hexafluorophosphate (BOP) (5.5 g, 0.124 mmol), 1-hydroxybenzotriazole (HOBt) 1.9 g (1.24×10−2 mol) and N, N′-diisopropylethylamine (DIEA) 2.2 ml (0.124 mmol) were dissolved in DMF (10 ml). The solution was added to a suspension of the polypseudorotaxane (29 g, the number of α-CD: 120) in DMSO/DMF (20 ml), and the reaction mixture was stirred at room temperature for 6 h. Here, volume ratio of DMSO and DMF was varied (Table. 8). After that, the mixture was poured into excess acetone to precipitate crude products and to remove BOP, HOBt, DIEA and unreacted α,ω-diamino-PEG. The precipitate was collected by centrifugation and washed with ethanol and pure water to remove impurities including free α-CDs. The resulting precipitate was dried in vacuo at room temperature to obtain Z-Tyr-terminated polyrotaxanes as white powders (Table. 8).
8TABLE 8Preparation of Z-L-Tyr-terminated polyrotaxanesSolvent# of(DMF/α-% ofYieldSample codeDMSO)CDathreadingbMnc(%) 50α/E20-TYR-Z for 185/15502269,2306 85α/E20-TYR-Z for 290/108537103,25026120α/E20-TYR-Z for 3100/0 12053137,27028aCalculated from 1H-NMR spectra. Stoichiometric (calculated) number of α-CD onto a PEG (Mn: 20,000) is ca. 227, assuming one α-CD molecule threads two ethylene glycol units. b% of threading = [Total # of α-CD]/[calculated # of α-CD] × 100 cCalculated from 1H-NMR spectra.


[0208] c) Synthesis of Carboxyethylester-Polyrotaxanes


[0209] Carboxyethylester polyrotaxanes (CEE-polyrotaxanes) was prepared according to our method. The Z-Tyr-terminated polyrotaxanes and succuinic anhydride (same mol. of hydroxyl groups in the Z-Tyr-terminated polyrotaxanes) were dissolved in dry pyridine and stirred at room temperature. The reaction mixture was poured into excess ether and washed with ether three times. The precipitate was collected by centrifuging and dried under in vacuo to give the CEE-polyrotaxanes. The degree of substitution of CEE groups in the polyrotaxane was estimated from the ratio of the methylene peak of CEE (2.3 ppm) and C(1)H of α-CD (4.9 ppm) on 1H-NMR spectra. In this synthetic condition, all the primary hydroxyl groups were converted to the CEE (Table 9).
9TABLE 9Synthesis of carboxyethylester-polyrotaxanes# of CEE/# of α-CD/moleaTotalSample codemolea(% of threading)Mna300CEE-α50/E20-TYR-Z for 130050 (22) 99,230510CEE-α85/E20-TYR-Z for 251085 (37)154,250720CEE-α120/E20-TYR-Z for 3720120 (53) 209,270aCalculated from 1H-NMR spectra.


[0210] d) Conjugation of Maltose with CEE-Polyrotaxanes (FIG. 22)


[0211] β-Maltosylamine (Mal-amine) was prepared by the method of Kobayashi et al [Kobayashi, K.; Tawada, E.; Akaike, T.; Usui, T. Biochim. Biophys. Acta 1997, 1336, 117-122. (yield: 85%). The CEEpolyrotaxanes were dissolved in dry DMSO. A solution of BOP, HOBt and DIEA in DMSO was added to the solution. The feed conditions were summarized in Table 10. The reaction mixture was stirred at 25° C. for several ten minutes. Then, Mal-amine in DMSO was added (final concentration of Mal-amine: 8.8 mM) and stirred at 25° C. for 10 h. The solution was pored into an excess acetone, and then, the crude products were purified by dialysis against water using Spectra/Por@ CE 6 (MWCO: 8,000) to obtain the maltose-polyrotaxane conjugates (1-3) as white powders (yields: 70-80%). In a similar maruier, a maltose-α-CD conjugate (4) and maltose-poly(acrylic acid) conjugates (5) were synthesized. The degree of substitution of maltose in the polyrotaxane was calculated from the ratio of the C(1)H and C(1′) of maltose (2H, 5.3 ppm) and C(1)H of α-CD (1H, 4.9 ppm) on the 1H-NMR spectra.


[0212] 1d 1H-NMR [750 MHz, D2O containing 0.05v/v % t-BtOH ppm]: δ7.9-7.3 (d, NH's), 5.3-5.0 (C(1)H and C(1′)H of maltose, d, 460 H), 5.1-4.6 (C(1)H of α-CD, d, 300 H), 3.9-3.3 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD and C(3)H, C(3′)H, C(5)H, C(5′)H, C(6)H, C(6′)H, C(4)H, C(4′)H, C(2)H and C(2′)H of maltose, m, 4560 H), 3.55 (CH2 of PEG, s, 455 H), 2.9-2.3 (CH2 of carboxyethylester, m, 1200 H)..


[0213] 2d 1H-NMR [750 MHz, D2O containing 0.05v/v % t-BtOH ppm]: δ7.9-7.3 (d, NH's), 5.3 (C(1)H and C(1′)H of maltose, d, 488 H), 5.1-4.6 (C(1)H of α-CD, d, 480H), 3.9-3.3 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD and C(3)H, C(3′)H, C(5)H, C(5′)H, C(6)H, C(6′)H, C(4)H, C(4′)H, C(2)H and C(2′)H of maltose, m, 5990 H), 3.55 (CH2 of PEG, s, 455 H), 2.9-2.3 (CH2 of carboxyethylester, m, 2040 H).


[0214] 3d 1H-NMR [750 MHz, D2O containing 0.05v/v % t-BtOH ppm]: δ7.9-7.3 (d, NH's), 5.3 (C(1)H and C(1′)H of maltose, d, 480 H), 5.2-4.6 (C(1)H of α-CD, d, 720H), 3.9-3.3 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD and C(3)H, C(3′)H, C(5)H, C(5′)H, C(6)H, C(6′)H, C(4)H, C(4′)H, C(2)H and C(2′)H of maltose, m, 7200 H), 3.55 (CH2 of PEG, s, 455 H), 2.9-2.3 (CH2 of carboxyethylester, m, 2880 H).


[0215] 4 1H-NMR [750 MHz, D2O containing 0.05v/v % t-BtOH ppm]: δ7.9-7.3 (d, NH's), 5.3 (C(1)H and C(1′)H of maltose, d, 6 H), 5.2-4.6 (C(1)H of α-CD, bs, 6 H), 4.2-3.2 (C(3)H, C(5)H, C(6)H, C(4)H and C(2)H of α-CD and C(3)H, C(3′)H, C(5)H, C(5′)H, C(6)H, C(6′)H, C(4)H, C(4′)H, C(2)H and C(2′)H of maltose, m, 48 H), 2.9-2.3 (CH2 of carboxyethylester, m, 24 H).


[0216] 5d 1H-NMR [750 MHz, D2O containing 0.05v/v % t-BtOH ppm]: δ8.1-7.3 (d, NH's), 5.3 (C(1)H and C(1′)H of maltose, d, 470 H), 4.2-3.2 (C(3)H, C(3′)H, C(5)H, C(5′)H, C(6)H, C(6′)H, C(4)H, C(4′)H, C(2)H and C(2′)H of maltose, m, 2820 H), 3.7 (CH of PAA, s, 87 H), 3.7 (CH of PAA, s, 87 H), 1.9 (CH of PAA, s, 174 H)
10TABLE 10Synthetic condition of maltose-polyrotaxane conjugatesConc. ofBOPHOBtDIEASample codeCEE (mM)(mM)(mM)(mM)1a3.01.51.51.51b3.03.03.03.01c3.04.54.54.51d3.06.06.06.02a3.31.71.71.72b3.33.33.33.32c3.35.05.05.02d3.36.66.66.63a3.41.71.71.73b3.43.43.43.43c3.45.15.15.13d3.46.86.86.84 3.84.64.64.65a7.04.04.04.05b7.07.07.07.05c7.011.011.011.05d7.017.517.517.5


[0217] Determination of Molecular Weights


[0218] Average molecular weights of the maltose-polyrotaxane conjugates were calculated by 1H-NMR measurements and gel permeation chromatography (GPC). Examples of GPC data and the molecular weights were shown in FIG. 23(a) and Table 11, respectively. As for the GPC, both the number average molecular weight (Mn) and the weight average molecular weight (Mw) were calculated from a calibration curve of pullulan standard (FIG. 23(b)) (Column: TSKgel G-5000HHR+TSKgel G-3000HHR, Tosoh Co. Ltd., Tokyo, Japan; eluent: DMSO, Flow rate: 0.8 ml/min; and detection: optical rotation.), where only the small change of retention time varied the Mn. The obtained data of Mn from the GPC were well consistent with those from 1H-NMR, suggesting that the Mn calibrated by pullulan did not include any artifacts of the instruments such as pressure variations,
11TABLE 11Molecular Weights and Molecular Weight Distributionof The ConjugatesSampleMn codeaNMRbGPCcMwcMw/Mn1d181,300199,400334,0001.72d237,500257,700412,3001.63d291,100293,700469,9001.64 2,5402,8604,2901.55d109,600102,300358,0003.5aMn of PEG for 1-3: 20,000, Mn of poly(acrylic acid) for 5: 25,000, bCalculated from 1H-NMR spectra, cCalculated from a calibration curve using pullulan standard.


[0219]

1
H-NMR Charts of 1d, 2d, 3d, 4 and 5d (Solvent: 0.1 M Phosphate Buffer (Using D2O, pD 7.4) Containing 1 mM CaCl2 and 0.1 mM MgCl2) were Shown in FIGS. 24-28.


[0220] The effect of the mechanically locked structure in the maltosepolyrotaxane conjugates on multivalent interaction was assessed using the Con A-induced hemagglutination inhibition assay (FIG. 29). FIG. 29 shows the Relative potency of Con-A-induced hemagglutination inhibition based on the minimum inhibitory concentration (MIC) of the maltose unit (concentration of Con A: 1.96 mg/mL, n=3, mean ±S.E.M.). The hemagglutination experiments were carried out in a 0.1 M PBS buffer (pH 7.4) containing 0.1 mM CaCl2 and 0.1 mM MnCl2. The sample codes are consistent with those in Table 7.


[0221] Inhibition of Con-A Induced Hemagglutination


[0222] The concentration of Con A was fixed to be fourfold minimum concentration required for hemagglutination of erytluocyte (Kawagishi, H.; Yamawaki, M., Isobe, S.; Usui, T.; Kimura, A.; Chiba, S. J. Biol. Chem. 1994, 269, 1375-1379), Twenty μl of a 3% erythrocyte (Rat blood) suspension in a 0.1 M phosphate buffer (PBS, pH7.4) containing 0.1 mM CaCl2 and 0.1 mM MgCl2 was pipetted into each well of the twofold dilution series of Con A (20 μl) in 96-holes microtiter plate, and incubated at 37° C. for 1 h. The minimum concentration of Con A was determined and its fourfold concentration was used for the following Con A-induced hemagglutination assay.


[0223] An aliquot (20 μl) of Con A (7.83 μg/ml) in the buffer was added to each hole of 96-holes microfiter plates. The malotose conjugates dissolved in the buffer with various concentrations were added to the each hole (20 μl) and incubated at 37° C. for 1 h Then, 3% erythrocyte suspension (40 μl) was added to the holes and incubated at 37° C. for 1 h. Agglutination of erytlrocytes was observed and the minimum inhibitory concentration (MIC) of maltose unit was determined. All the experiments were carried out triplicate.


[0224] Relative potency was calculated from the ratio of MICs of the maltose-polyrotaxane conjugate and the maltose itself. The relative potency of Mal-α/E20-TYR-Zs (1-3) and Mal-PAA (5) increased with the number of maltose groups up to around 120, although the absolute values were varied. On the other hand, the relative potency of Mal-α-CD (4) was very small, and the number of maltose groups per α-CD is the same as that in 1c and 2d. The potency increase in 1-3 and 5 can be attributed to the chelate effect and was consistent with the multivalent effects in terms of increasing the number of saccharide groups conjugated with the polymer backbone. The relative potencies of 3 and 5 decreased with a further increase in the number of maltose groups (3d and 5d). This result is well consistent with previous glycopolymer systems: all of the maltose groups conjugated with the polymer backbone cannot necessarily bind to the binding sites of Con A, and hence unavailable maltose groups are buried in 3d and 5d. However, the relative potency of 2d was significantly higher than those in 1d, 3d, and 5d despite a similar number of maltose groups (FIG. 29).


[0225] The most dominant parameter to enhance the relative potency observed in 2d should be the threading % of α-CDs. A 1H NMR signal of 2d was very sharp, although those of 1d and 3d were broadened. The order of sharpening the signals in terms of α-CD threading was 38% (2d)>>22% (1d)>53% (3d). One of the possible reasons for the sharpening could be the high mobility of Mal-α-CDs in the mechanically locked structure of the polyrotaxane backbone, which has shorter correlation times. The spin-spin relaxation time (TV) of C(1)H (δ: 5.1 ppm) of maltose groups in 2d was much longer than those of 1d and 3d (Table 12).
12TABLE 12T2 of the C(1)H of Maltose Groups in Each Conjugateasampleα-CDtotal nocodethreading (%)of MalT2 [s]1d222300.1162d382440.2303d532400.0834 30.2375d2400.035a0.1 M phosphate buffer (using D2O, pD 7.4) containing 1 mM CaCl2 and 0.1 mM MgCl2 was used.


[0226] In addition, 2d exhibited almost the same T2 as Mal-α-CD (4). These results indicate that the maltose groups in 2d maintain a mobility similar to that in 4. On the other hand, the maltose mobilities of 3d and Mal-PAA (5d) were lower than the others. Taking these results into account, it is considered that the high mobility of the maltose groups in the polyrotaxane with the appropriate threading % of α-CDs contributes to the enhanced Con A binding. Of course, the high mobility was not the only dominant factor. Even with almost the same values of T2 and number of maltose groups per α-CD, the mechanically locked structure of the polyrotaxane (2d) exhibited an inhibitory effect far superior to that of α-CD (4). So far, synthetic multivalent ligands have been designed so as to increase enthalpy gain using the flexible linker of saccharides. However, with an increase in the valency, those ligands are thermodynamically unfavorable due to spatial mismatches between the saccharides and binding protein during clustering. The mechanically locked structure of Mal-α/E20-TYR-Z with the typical α-CD threading % can have favorable thermodynamic parameters in the multivalent interaction. Presumably, the high mobility of Mal-α-CDs reduces the special mismatches between maltose and Con A binding sites, resulting in preventing the entropic loss and gaining the enthalpy during binding Therefore, it is concluded that the combination of (i) multiple copies of ligands and (ii) their supramolecular mobility along the mechanically locked structure should contribute to significant enhancement of the multivalent interaction due to a reduction of the special mismatches of binding.


Claims
  • 1. A multivalently interactive molecular assembly comprising: a plurality of at least one of functional groups and ligands, wherein a ratio between Rh and Rg which is expressed by Rh/Rg is 1.0 or less, where Rh is a hydrodynamic radius calculated from dynamic light scattering (DLS) assay performed in aqueous solution; and Rg is a radius of gyration determined based on the Zimm plot generated using data obtained by static light scattering (SLS) assay.
  • 2. A multivalently interactive molecular assembly comprising: a plurality of at least one of functional groups and ligands, wherein a diffusion constant D calculated from a dynamic light scattering assay performed in aqueous solution increases as scattering vector constant K increases.
  • 3. A multivalently interactive molecular assembly comprising; a plurality of cyclic molecules; a linear molecule which is threaded through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule, wherein at least two of the plurality of cyclic molecules are substituted with at least one of a functional group and a ligand, wherein a ratio T2/T2′ ranging from 0.4 to 1 is satisfied between a spin-spin relaxation time T2 measured on the substituent, and, a spin-spin relaxation time T2′ measured on a similarly positioned moiety of a substituent substituted with a cyclic molecule which is not threaded through with the linear molecule.
  • 4. A multivalently interactive molecular assembly according to claim 3, characterized in that the bulky substituents degrade when the multivalently interactive molecular assembly is in vivo.
  • 5. A multivalently interactive molecular assembly according to claim 3, wherein the multivalently interactive molecular assembly is a polyrotaxane.
  • 6. A multivalently interactive molecular assembly according to claim 3, wherein the cyclic molecules are cyclodextrin.
  • 7. A multivalently interactive molecular assembly according to claim 3, wherein the functional group contains a caboxyl group at an end thereof.
  • 8. A multivalently interactive molecular assembly according to claim 7, wherein the functional group containing a caboxyl group at an end thereof is a carboxyalkoxycarbonyl group.
  • 9. A multivalently interactive molecular assembly according to claim 3, wherein the cyclic molecules are substituted with a ligand that is a sugar ligand.
  • 10. A multivalently interactive molecular assembly according to claim 3, wherein the cyclic molecules are cyclodextrin molecules, and a peak area of C6 primary hydroxyl group, C2 secondary hydroxyl group and C3 secondary hydroxyl group in at least two of the cyclodextrin molecules are reduced by 10 to 95% than a peak area of the corresponding hydroxyl group in a cyclodextrin with no substituents, as determined by a two-dimensional 1H-NMR spectroscopy.
  • 11. A capturing agent comprising: a multivalently interactive molecular assembly which can capture an object of interest, wherein the multivalently interactive molecular assembly comprises: a plurality of cyclic molecules; a linear molecule which is threaded through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule; wherein at least two of the plurality of cyclic molecules are substituted with one of a functional group and a ligand, wherein one of the functional group and the ligand is capable of capturing an object of interest.
  • 12. A drug carrier comprising: a multivalently interactive molecular assembly, wherein the multivalently interactive molecular assembly comprises: a plurality of cyclic molecules; a linear molecule which is threaded through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule, wherein at least two of the plurality of cyclic molecules are substituted with one of a functional group and a ligand, wherein one of the functional group and the ligand is capable of bonding a drug therewith.
  • 13. A calcium chelating agent comprising: a multivalently interactive molecular assembly, wherein the multivalently interactive molecular assembly comprises: a plurality of cyclic molecules; a linear molecule which is threaded through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule, wherein at least two of the plurality of cyclic molecules are substituted with a functional group containing caboxyl group at an end thereof, wherein the functional group is capable of chelating calcium.
  • 14. A drug enhancer comprising: a multivalently interactive molecular assembly, wherein the multivalently interactive molecular assembly comprises: a plurality of cyclic molecules; a linear molecule which is threaded through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule, wherein at least two of the plurality of cyclic molecules are substituted with a functional group containing caboxyl group at an end thereof, wherein the functional group is capable of enhancing efficacy of a drug used therewith.
  • 15. A drug enhancer according to claim 14, wherein the at least two of the plurality of cyclic molecules are multivalently interactive molecular assembly substituted with a ligand.
  • 16. Polyrotaxane which can be used in a multivalently interactive molecular assembly, wherein the multivalently interactive molecular assembly comprises: a plurality of cyclic molecules; a linear molecule which threads through the cyclic molecules to hold the cyclic molecules together; and bulky substituents capping both ends of the linear molecule; wherein at least two of the plurality of cyclic molecules are substituted with one of functional groups and ligands.
Priority Claims (1)
Number Date Country Kind
2002-052474 Feb 2002 JP
Continuation in Parts (1)
Number Date Country
Parent 10230394 Aug 2002 US
Child 10679499 Oct 2003 US