Direct electron transfer-type oxidoreductase-modified molecular recognition element

Information

  • Patent Grant
  • 11293921
  • Patent Number
    11,293,921
  • Date Filed
    Wednesday, October 2, 2019
    5 years ago
  • Date Issued
    Tuesday, April 5, 2022
    2 years ago
Abstract
A molecular recognition element comprising a target molecule-recognizing portion, and a direct electron transfer-type oxidoreductase linked to the target molecule-recognizing portion.
Description
SEQUENCE LISTING SUBMISSION VIA EFS-WEB

A computer readable text file, entitled “SequenceListing.txt,” created on or about Oct. 2, 2019 with a file size of about 28 kb contains the sequence listing for this application and is hereby incorporated by reference in its entirety.


TECHNICAL FIELD

The present invention relates to a novel molecular recognition element that can be used for biosensing technology such as an immunosensor.


BACKGROUND ART

In a conventional immunoassay such as ELISA using an antibody labeled with an enzyme, or the like, it is necessary to separate (Bound/Free (B/F) separation) an antibody not bound to an antigen by performing a washing operation such as lateral flow after a reaction between an antigen and an antibody in order to remove a nonspecific signal. However, such a B/F separation operation complicates the procedures and the efficiency of the B/F separation may affect the signal accuracy.


As the enzyme used for labeling an antibody, a peroxidase, and an alkali phosphatase are often used. In Non-Patent Literature 1, an electrochemical type immunoassay using an antibody labeled with a glucose oxidase (GOD) is disclosed.


CITATION LIST

[Non-Patent Literature 1] FEBS LETTERS, June 1977 DOI: 10.1016/0014-5793 (77) 80317-7


SUMMARY OF INVENTION

In the method disclosed in Non-Patent Literature 1, electrons generated by a reaction of the GOD and a substrate are converted to a hydrogen peroxide, and the hydrogen peroxide diffuses into the solution and is reduced on the surface of an electrode to generate a signal. Therefore, in the reaction system, a signal that would be generated by an antibody-GOD existing in the vicinity of the electrode due to nonspecific adsorption, etc. becomes a noise, and therefore it is required to undergo a careful cleaning step. In addition, when nonspecific adsorption is strong, or an antigen, which is the target molecule, has been adsorbed nonspecifically, it is difficult to completely remove the nonspecific signal. Further, depending on the environment between the GOD bound to the antibody and the electrode, there is a limitation on removing noise components by washing.


One aspect of the invention is to provide a novel molecular recognition element that can be used in biosensing technology such as an immunosensor.


According to an embodiment of the invention, a molecular recognition element comprising a target molecule-recognizing portion, and a direct electron transfer-type oxidoreductase linked to the target molecule-recognizing portion is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the target molecule-recognizing portion comprises a target molecule-recognizing protein, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein a target molecule is an antigen and the target molecule-recognizing portion is an antibody against the antigen, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the direct electron transfer-type oxidoreductase is an oxidoreductase comprising an electron-transferring domain, or an electron-transferring subunit, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the electron-transferring domain is a heme-containing domain, or the electron-transferring subunit is a heme-containing subunit, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the oxidoreductase is a glucose dehydrogenase, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase are linked by a cross-linker, is provided.


According to another embodiment of the invention, the molecular recognition element, wherein the molecular recognition element comprises a fusion protein of the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase, is provided.


According to another embodiment of the invention, a sensor comprising an electrode, and the aforedescribed molecular recognition element immobilized on the electrode, is provided.


According to another embodiment of the invention, the sensor wherein the molecular recognition element is immobilized on the electrode by means of a monolayer forming molecule, is provided.


According to another embodiment of the invention, a method for measuring a target molecule comprising introducing a sample containing a target molecule into the aforedescribed sensor; and detecting a signal based on the target molecule, is provided.


According to another embodiment of the invention, a reagent for measuring a target molecule comprising the aforedescribed molecular recognition element, is provided.


According to an embodiment of the present invention, a molecular recognition element capable of directly transferring electrons to an electrode can be constructed by linking a direct electron transfer-type oxidoreductase to a molecular recognition portion such as an antibody.


Since a direct electron transfer signal can be detected based on the occurrence of the specific antigen-antibody binding, a system of measurement that is not affected by nonspecific binding, and does not require a careful washing operation can be constructed.


From the above, construction of an electrochemical immunosensor free from the influence of nonspecific adsorption can be expected.





BRIEF DESCRIPTION OF DRAWINGS


FIG. 1 shows a cross-linking procedure of anti-CRP IgG and GDH.



FIG. 2 shows the result of polyacrylamide gel electrophoresis for confirming the interaction between IgG-GDH and CRP (photograph).



FIG. 3 shows the measurement result of glucose oxidation current in a sensor comprising an IgG-GDH immobilized electrode.



FIG. 4A shows a preparation procedure of an anti-CRP half antibody (rIgG).



FIG. 4B shows a cross-linking procedure of an anti-CRP half antibody and GDH.



FIG. 5 shows the result of polyacrylamide gel electrophoresis and activity staining for confirming the interaction between rIgG-GDH and CRP (photograph).



FIG. 6 shows the measurement result of a glucose oxidation current in a sensor comprising a rIgG-GDH immobilized electrode.



FIG. 7 shows a preparation procedure of a fusion protein (GDH-scFv(GGGGS)) of an anti-CRP single-chain antibody and GDH.



FIG. 8 shows the result of polyacrylamide gel electrophoresis and activity staining for confirming the interaction between GDH-scFv(GGGGS) and CRP.



FIG. 9 shows the measurement result of a glucose oxidation current in a sensor comprising a GDH-scFv(GGGGS) immobilized electrode.





DESCRIPTION OF EMBODIMENTS

<Molecular Recognition Element>


The molecular recognition element comprises a target molecule-recognizing portion, and a direct electron transfer-type oxidoreductase linked to the target molecule-recognizing portion. Hereinafter, it may be referred to as the “molecular recognition element of the present invention”.


<Target Molecule>


There is no particular limitation on the type of target molecule, and examples thereof include a low molecular weight compound, a peptide, a protein, a hormone, a sugar, a toxin, a viral particle, and a metal.


<Target Molecule-Recognizing Portion>


A target molecule-recognizing portion can be selected according to the type of the target molecule, and examples thereof include an antibody capable of recognizing an antigen, which is the target molecule; a target molecule-recognizing protein such as a receptor protein capable of recognizing a hormone, which is the target molecule; a nucleic acid aptamer capable of recognizing a low molecular weight compound or a peptide, which is the target molecule; and a lectin capable of recognizing a sugar, which is the target molecule. Recognizing the target molecule includes binding to the target molecule.


When the target molecule-recognizing portion is a protein it preferably has at least 50 amino acids, e.g. at least 100 or 250 amino acids. For example it may have 50-500 amino acids. When the target molecule-recognizing portion is an antibody, the antibody may be IgG, IgE or IgA, a half antibody, or a single-chain antibody (scFv). Furthermore, it may be a partial fragment of the antibody. Such fragments retain their ability to recognize their target molecule.


<Direct Electron Transfer-Type Oxidoreductase>


A “direct electron transfer-type oxidoreductase” means a type of oxidoreductase capable of transferring an electron directly between an enzyme and an electrode. In the case of using the direct electron transfer-type oxidoreductase, electrons generated by the reaction can be transferred directly between the enzyme and the electrode without involvement of a redox substance, such as an artificial electron acceptor (electron-transferring mediator) e.g. redox molecules.


The direct electron transfer-type oxidoreductase may include an electron-transferring subunit or an electron-transferring domain. Examples of the electron-transferring subunit include a subunit containing heme, and examples of the electron-transferring domain include a heme-containing domain. Examples of the heme-containing subunit, or domain include a subunit or a domain containing heme c or heme b, and more specifically, a subunit or a domain containing cytochrome such as cytochrome c, or cytochrome b.


As an oxidoreductase having a domain containing heme C, for example, a fusion protein of PQQ glucose dehydrogenase (PQQGDH) and cytochrome c as disclosed in International Publication No. WO 2005/030807 can be used.


Further, a cholesterol oxidase, and a quinoheme ethanol dehydrogenase can also be used.


Meanwhile, as an oxidoreductase including a heme-containing subunit, an oligomeric enzyme having at least a catalytic subunit and a heme-containing subunit is preferably used.


A large number of oligomeric-type oxidoreductases including a heme-containing subunit are known, and examples thereof include glucose dehydrogenase (GDH), sorbitol dehydrogenase (sorbitol DH), D-fructose dehydrogenase (fructose DH), D-glucoside-3-dehydrogenase (glucoside-3-dehydrogenase), cellobiose dehydrogenase, and lactate dehydrogenase.


Among them, glucose dehydrogenase (GDH) is preferable, and the catalytic subunit of GDH can contain flavin adenine dinucleotide (FAD).


An example of the GDH having a catalytic subunit containing FAD is a GDH derived from Burkholderia cepacia. An example of the amino acid sequence of the catalytic subunit (a subunit) is shown as SEQ ID NO: 3. The catalytic subunit may have a mutation, such as substitution, deletion, and insertion. Examples of a mutant of the catalytic subunit of FAD-dependent GDH derived from Burkholderia cepacia include a mutant in which amino acid residues at positions 472 and 475 are substituted (WO 2005/103248), a mutant in which amino acid residues at positions 326, 365 and 472 are substituted (Japanese Patent Laid-Open No. 2012-090563), and a mutant substituted at positions 365 as well as 326, 472, 475, 529, etc. (WO 2006/137283). In a further preferred aspect the GDH has a mutant at position 463 (to cysteine) in the catalytic subunit, as used in the Examples described herein. However, the mutant is not limited to these, and may contain mutations at other positions. Thus in a preferred aspect the GDH comprises a catalytic subunit having an amino acid sequence as set forth in SEQ ID NO: 3 or a sequence with up to 10 mutations, e.g. 1, 2, 3, 4 or 5 mutations. Such mutations include substitutions, deletions and insertions (preferably of a single amino acid only), preferably as described above.


There is no particular limitation on the type of a heme-containing subunit, and examples thereof include a cytochrome-containing subunit (β subunit) of a GDH derived from Burkholderia cepacia; and an example of its amino acid sequence is shown as SEQ ID NO: 4. The cytochrome-containing subunit may have a mutation such as substitution, deletion, insertion, etc. Thus in a preferred aspect the GDH comprises a cytochrome-containing subunit having an amino acid sequence as set forth in SEQ ID NO: 4 or a sequence with up to 10 mutations, e.g. 1, 2, 3, 4 or 5 mutations. Such mutations include substitutions, deletions and insertions (preferably of a single amino acid only).


GDH may be an oligomer constituting the above-mentioned catalytic subunit and a cytochrome-containing subunit, but may also include a regulatory subunit in addition to the catalytic subunit and cytochrome-containing subunit. An example of the amino acid sequence of the regulatory subunit (γ subunit) of a GDH derived from Burkholderia cepacia is shown as SEQ ID NO: 2. However, the γ subunit may have a mutation, such as substitution, deletion, or insertion. Thus in a preferred aspect the GDH comprises a regulatory subunit having an amino acid sequence as set forth in SEQ ID NO: 2 or a sequence with up to 10 mutations, e.g. 1, 2, 3, 4 or 5 mutations. Such mutations include substitutions, deletions and insertions (preferably of a single amino acid only).


As an example, the nucleotide sequence of a chromosomal DNA fragment including the GDH γ subunit gene, a subunit gene, and f3 subunit gene of the Burkholderia cepacia KS1 strain is shown as SEQ ID NO: 1. Three open reading frames (ORFs) are present in the nucleotide sequence, and the first ORF from the 5′-end side (nucleotide numbers 258-761) encodes the γ subunit (SEQ ID NO: 2), the second ORF (nucleotide numbers 764-2380) encodes the α subunit (SEQ ID NO: 3), and the third ORF (nucleotide numbers 2386-3660) encodes the β subunit (SEQ ID NO: 4). Thus in a preferred aspect the GDH comprises an α and β subunit, and optionally a γ subunit, encoded, respectively, by a nucleotide sequence as set forth in SEQ ID NO: 3, 4 and 2 (or collectively as set forth in SEQ ID NO: 1) or a sequence with up to 10 mutations, e.g. 1, 2, 3, 4 or 5 mutations. Such mutations include substitutions, deletions and insertions (preferably which result in mutation of a single amino acid only in the encoded sequence), preferably as described hereinbefore.


<Linkage of Target Molecule-Recognizing Portion and Direct Electron Transfer-Type Oxidoreductase>


Although there is no particular limitation on the method of linking a target molecule-recognizing portion and a direct electron transfer-type oxidoreductase insofar as the target molecule-recognizing capability of the target molecule-recognizing portion, and the enzyme activity of the direct electron transfer-type oxidoreductase are not significantly retarded, it is preferable that the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase are linked with a covalent bond(s). In an embodiment, the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase are linked with a cross-linker.


A target molecule-recognizing portion and a direct electron transfer-type oxidoreductase can be linked, for example, by introducing a cross-linker (crosslinkable reactive group) into the target molecule-recognizing portion, and by reacting a reactive functional group, such as a thiol group, an amino group, and a carboxyl group, possessed by the direct electron transfer-type oxidoreductase with the cross-linker so that the two are cross-linked.


Further, a target molecule-recognizing portion and a direct electron transfer-type oxidoreductase can be linked, for example, by introducing a cross-linker (crosslinkable reactive group) into the direct electron transfer-type oxidoreductase, and by reacting a reactive functional group, such as a thiol group, an amino group, and a carboxyl group, possessed by the target molecule-recognizing portion with the cross-linker so that the two are cross-linked.


The reactive functional group may be a functional group originally possessed by a target molecule-recognizing portion or a direct electron transfer-type oxidoreductase, or may be a functional group artificially introduced by amino acid substitution, amino acid introduction, or the like. In addition, the reactive functional group may be a plurality of unspecified functional groups, such as amino groups present in a protein, or one to several specified functional groups such as thiol groups present in a protein.


For example, when a target molecule-recognizing portion is an IgG antibody, examples of the above may include a thiol group in a half antibody (rIgG) generated by reducing an antibody (IgG), and with respect to a direct electron transfer-type oxidoreductase, examples of the above may include a thiol group of a cysteine residue present in the amino acid sequence of the direct electron transfer-type oxidoreductase.


As a cross-linker, a publicly known cross-linker can be used. Examples of a cross-linker that reacts with a thiol group include a maleimide compound, a haloacetic acid compound, a pyridyl disulfide compound, a thiosulfone compound, and a vinyl sulfone compound. Meanwhile, examples of a cross-linker that reacts with an amino group include an N-hydroxysuccinimide (NHS) ester compound, an imido ester compound, a pentafluorophenyl ester compound, and a hydroxymethyl phosphine compound. Further, examples of a cross-linker that reacts with a carboxyl group include an oxazoline compound. In a preferred aspect the cross-linker is GMBS as described in the Examples.


In another embodiment, by forming a fusion protein of a target molecule-recognizing portion and a direct electron transfer-type oxidoreductase, the two are linked together.


The fusion protein may be formed, for example, by constructing a gene construct in which a nucleotide sequence encoding a direct electron transfer-type oxidoreductase, and a nucleotide sequence encoding a target molecule-recognizing portion are linked such that the two are translated by combining the respective reading frames to be expressed as a fusion protein of the target molecule-recognizing portion, and the direct electron transfer-type oxidoreductase; and then making an appropriate host express the gene construct. Either of the target molecule-recognizing portion or the direct electron transfer-type oxidoreductase may be on the N-terminal side of the fusion protein. Alternatively, the two may be linked via an appropriate peptide linker. Furthermore, a tag sequence for detection or purification may be added to a fusion protein.


A nucleotide sequence encoding a direct electron transfer-type oxidoreductase may be appropriately selected corresponding to the type of the direct electron transfer-type oxidoreductase, and a known sequence can be utilized. Examples thereof include the nucleotide sequence encoding a GDH derived from the aforedescribed Burkholderia cepacia. Such sequences are described hereinbefore.


Also, a nucleotide sequence encoding a target molecule-recognizing portion may be appropriately selected corresponding to the type of the target molecule-recognizing portion and a known sequence such as a nucleotide sequence encoding an antibody can be utilized. Examples of the nucleotide sequence encoding an anti-CRP single-chain antibody include the sequence described in Journal of Bioscience and Bioengineering, Volume 105, Issue 3, March 2008, Pages 261-272.


Preparation, expression in a host, purification, and the like of a DNA encoding a fusion protein can be performed by a known genetic recombination technique.


<Sensor>


A sensor according to an embodiment of the present invention includes an electrode and a molecular recognition element immobilized on the electrode. Since a direct electron transfer-type oxidoreductase is used, a structure without an electron-transferring mediator as described above is possible.


As the electrode, an electrode composed of a known electrode material is considered, and examples thereof include a gold electrode, a platinum electrode, and a carbon electrode.


The sensor includes an electrode, on which the molecular recognition element of the present invention is immobilized, as a working electrode, and it may further include a counter electrode (platinum, etc.) and/or a reference electrode (Ag/AgCl, etc.).


The sensor may further include a constant-temperature cell for receiving a test sample, a power supply for applying a voltage to the working electrode, an ammeter, a recorder, and the like.


The structure of such an enzyme sensor is well known in the relevant art, and described, for example, in “Biosensors-Fundamental and Applications”, Anthony P. F. Turner, Isao Karube, and Geroge S. Wilson; Oxford University Press 1987.


In immobilizing the molecular recognition element of the present invention on an electrode, it is necessary to immobilize the molecular recognition element on the electrode in a state where the oxidoreductase included in the molecular recognition element is placed close to the electrode so that the oxidoreductase can function as a direct electron transfer-type oxidoreductase. In this regard, it is said that the distance limit allowing direct electron transfer in a physiological reaction system is 1 to 2 nm. Therefore, it is preferable to place the element such that the distance between the oxidoreductase molecule and the electrode becomes 1 to 2 nm or less in order not to compromise the electron transfer from the oxidoreductase to the electrode.


There is no particular restriction on the method of immobilization, and its examples include a method of chemically immobilizing the molecular recognition element on the electrode with a cross-linker, or the like, a method of indirectly immobilizing the molecular recognition element on the electrode using a binder, or the like, and a method of physically adsorbing the molecular recognition element on the electrode.


As a method of chemically immobilizing the molecular recognition element on the electrode with a cross-linker, or the like, a method of directly immobilizing the molecular recognition element on the electrode may be used, and additionally, for example, there is a method as disclosed in Japanese Patent Laid-Open No. 2017-211383. It is a method in which a monolayer (self-assembled monolayer (SAM)) forming molecule is immobilized on the electrode, and the molecular recognition element is immobilized by means of the SAM forming molecule.


A monolayer forming molecule is a compound capable of binding to an electrode, and capable of binding the molecular recognition element, and is a compound capable of forming a monolayer when a plurality of the molecules are unidirectionally bound on the electrode surface. By using a monolayer forming molecule, the distance between the electrode and the enzyme molecule can be controlled.


The monolayer forming molecule preferably has a first functional group having affinity for the electrode, a spacer site, and a second functional group capable of reacting with a functional group of the molecular recognition element. More preferably it has a structure where the first functional group having affinity for the electrode is bound to the first end of the spacer site, and the second functional group capable of reacting with the functional group of the molecular recognition element is bound to the second end of the spacer site. Examples of the first functional group having affinity for the electrode include, when the electrode is metallic, a thiol group, and a dithiol group, and when the electrode is carbon, pyrene, and porphyrin.


Examples of the second functional group capable of reacting with a functional group of the molecular recognition element include a succinimide group when it is reacted with an amino group of the molecular recognition element (including the terminal amino group and the side chain amino group), and an oxazoline group when it is reacted with a carboxyl group of the molecular recognition element (including a terminal carboxyl group and a side chain carboxyl group).


Examples of a monolayer forming molecule having a thiol group, or a dithiol group include compounds having the following structures.


In this regard, L is a spacer, and X is a functional group capable of reacting with a functional group of the molecular recognition element. Examples thereof include a succinimide or its ester and a thiol. Examples of the type of spacer include alkylene having 1 to 20 (e.g. 3 to 7) carbon atoms, alkenylene having 1 to 20 (e.g. 3 to 7) carbon atoms, alkynylene having 1 to 20 (e.g. 3 to 7) carbon atoms, polyethylene glycol having a polymerization degree of 2 to 50, and an oligopeptide having 1 to 20 amino acid residues, or combinations of such spacers. In the alkylene, alkenylene, or alkynylene, one or more —CH2— may be replaced by —O—.

SH-L-X  (1)
X-L-S—S-L-X  (2)


Examples of such a compound include the following DSH.




embedded image


Examples of a monolayer forming molecule having, for example, pyrene or porphyrin include a compound having the following structure.


In this regard, Py stands for pyrene, Po for porphyrin, L for a spacer, and X for a functional group capable of reacting with the functional group of the enzyme molecule. Examples of the type of the spacer include alkylene having 1 to 20 carbon atoms, alkenylene having 1 to 20 carbon atoms, alkynylene having 1 to 20 carbon atoms, polyethylene glycol having a polymerization degree of 2 to 50, and an oligopeptide having 1 to 20 amino acid residues.

Py-L-X  (3)
Po-L-X  (3′)


Examples of a monolayer forming molecule having, for example, pyrene include a compound having the following structure.




embedded image



<Method of Measuring Target Molecule>


A method of measuring a target molecule according to an embodiment of the present invention comprises introducing a sample containing a target molecule into the sensor, and detecting a signal based on the target molecule.


There is no particular limitation on the sample, insofar as it is a sample containing a target molecule, and it is preferably a tissue-derived sample. Examples thereof include a sample obtained from blood, a sample obtained from urine, a cell extract sample, and a cell culture liquid.


There is no particular limitation on the step of introducing a sample into a sensor, and examples thereof include adding a sample liquid onto the sensor, and dipping the sensor in a sample liquid.


The current value, potential value such as open circuit potential or resistance value such as impedance, which is associated with the direct electron transfer reaction caused by an oxidation-reduction reaction of a substrate when an enzyme reaction occurs in the vicinity of the electrode, greatly changes in the molecular recognition element of the present invention before and after the target molecule binds to the target molecule-recognizing portion. Therefore, the target molecule can be detected and quantified by detecting this change in the current value, potential value such as open circuit potential or resistance value such as impedance as a signal.


For example, in the case where the molecular recognition element of the present invention is a complex of an antibody and CyGDH (cytochrome GDH), and a sensor in which the complex is immobilized on the electrode is used, when a sample containing an antigen is added to the sensor, the antigen is bound to the antibody and the direct electron transfer ability of CyGDH changes. At this time, if glucose, which is a substrate of CyGDH, is added, an enzyme reaction occurs, and electrons generated therefrom are transferred to the electrode through heme to flow a current according to the amount of the antigen. Therefore, the amount of the antigen can be measured by measuring this current value.


In the measurement method of the present invention, since the concentration of a target molecule is detected by a current value based on direct electron transfer, there are advantages that a nonspecific signal can be suppressed, and B/F separation such as a washing step can be omitted.


<Reagent for Measuring Target Molecule>


The reagent for measuring a target molecule of the present invention includes the molecular recognition element of the present invention.


The reagent for measuring a target molecule may further contain a reaction substrate, a reaction buffer, or the like.


When analyzing a target molecule such as an antigen in a sandwich method, a target molecule binding substance different from the target molecule binding site included in the molecular recognition element of the present invention may be included.


For example, an antibody that binds to the target molecule (antigen) is prepared, and immobilized on the electrode.


A sample containing a target molecule is added to the electrode, on which the antibody is immobilized, to allow the target molecule to bind to the antibody (first antibody) on the electrode.


Then the molecular recognition element of the present invention comprising an antibody (second antibody) against the antigen and the direct electron transfer-type oxidoreductase linked thereto is added thereto to form a complex of the first antibody/the antigen/the second antibody/the oxidoreductase on the electrode. In other words, an oxidoreductase is recruited in the vicinity of the electrode according to the abundance of the antigen. By making the oxidoreductase react with the substrate there, an oxidation-reduction reaction occurs, and the electrons generated thereby are transferred between the electron-transferring site, or the electron-transferring subunit of the oxidoreductase and the electrode so that a current flows according to the abundance of the antigen. Therefore, the target molecule can be detected and quantified by measuring this current value, potential value such as open circuit potential or resistance value such as impedance. In other words, in contrast to the heretofore known immunoassay using an enzyme as a labeling agent, since the detection in principle relies on the measurement based on the direct electron transfer reaction, and the molecular recognition element which is not bound with the antigen and is free in the solution, is not present in the vicinity of the electrode to send out a signal, only the molecular recognition element, which is bound with the antigen, sends out a signal. Therefore, the treatment for eliminating nonspecific adsorption such as a washing operation can be greatly reduced as compared with the conventional method.


EXAMPLES

Next, the present invention will be more specifically described with reference to Examples. The present invention is not restricted in any way by these Examples.


Example 1

A CyGDH derived from B. cepacia was used as the GDH including a cytochrome c-containing subunit. The CyGDH derived from B. cepacia is an oligomeric enzyme constituted of 3 subunits of γ, α and β, and these 3 subunits are encoded by the gene having the nucleotide sequence of SEQ ID NO: 1.


In the present Example, a mutant was used, in which the amino acid residue at the 463-th position of the α subunit was substituted with a cysteine residue to be used for binding to IgG. Specifically, for the plasmid pTrc99Aγαβ for expressing GDH described in Japanese Patent Laid-Open No. 2012-090563, pTrc99Aγα(463C)β in which a mutation was introduced into the α subunit was used to express a mutated GDH. This was used in the following experiment.


By cross-linking the NH2 group of an antihuman CRP (C Reactive Protein) monoclonal antibody (mouse CRP-MCA, (Oriental Yeast Co., Ltd.), hereinafter IgG) and the SH group of a cysteine residue introduced into the α subunit of the cytochrome c-containing GDH produced as above using the cross-linker GMBS (Dojindo Molecular Technologies, Inc.), an IgG-GDH complex was produced. The specific procedure is shown in FIG. 1.


The CRP binding ability of the obtained IgG-GDH complex was examined by polyacrylamide gel electrophoresis and activity staining. The results are shown in FIG. 2. Comparing lane 1 (without CRP) and lane 1 (with CRP addition), the band near 800 kDa of lane 2 became thinner. This is conceivably because the molecular weight of the IgG-GDH complex was shifted to the higher molecular weight site due to binding of CRP to IgG, which indicated that the IgG-GDH complex was able to bind CRP.


Next, the above-described IgG-GDH complex was immobilized on the gold wire electrode whose surface was modified with a SAM-forming molecule (DSH).


The procedure is as follows.










TABLE 1





Electrode
Au wire (ϕ 0.5 mm, 6-7 cm)







Preparation of
Cleaning of Au surface









Enzyme

Soaked in Piranha sol. (H2O2:H2 SO4 = 1:3) 5h


electrode

Rinsed with Acetone









SAM modification











Soaked in SAM sol. (400 μL/500 μL tube) 24h




at 25° C.




20 μM DSH-SAM in Acetone




Washed by Acetone & 50 mM PPB (pH 7.5)









Enzyme modification











Soaked in Complex solution (300 μL/500 μL tube)




50 mM PPB (pH 7.5) 20h at 4° C.




IgG-GDH 0.03 mg/mL




GDH 0.015 mg/mL









Electrochemical Measurement









It was investigated whether direct electron transfer from the cytochrome c-containing subunit of GDH to the electrode occurred by a glucose oxidation reaction of GDH in the IgG-GDH complex by adding glucose to react in a solution not containing a mediator using the obtained electrode with the immobilized IgG-GDH complex.


The experimental procedure is as follows.









TABLE 2







Electrochemical Measurement


Electrode chips: DEP-chip (EP-P)


Uniscan multi-channel PG580RM


3-Electrode configuration;


  WE: Enzyme modified Au wire


 CE: Pt wire


 RE: Ag/AgCl (BAS RE-1B)


Cell volume: 2 mL


Test solution: PBS


Temperature: 25 ± 1° C.


Chronoamperometry: +200 mV vs. Ag/AgCl


Measurement (1-1)  Sample: 0~600 mg/dL Glucose


Measurement (1-2) Sample: 300 mg/dL Glucose + 0~10 mg/dL CRP


Measurement (2-1) Sample: 0~600 mg/dL Glucose


Measurement (2-2) Sample: 10 mg/dL CRP + 0~600 mg/dL Glucose









The results are shown in FIG. 3.


The IgG-GDH immobilized electrode exhibited the same level of glucose concentration-dependent oxidation current compared with an electrode with an immobilized unlabeled GDH (463 Cys) as the control.


This suggests that the IgG-GDH complex recruited into the vicinity of the electrode can transfer the electrons generated by the catalytic activity of GDH to the electrode.


Example 2

As the GDH including a cytochrome c-containing subunit, a wild-type GDH derived from B. cepacia was used. Using the plasmid pTrc99Aγαβ for expressing GDH described in Japanese Patent Laid-Open No. 2012-090563, a wild-type GDH was expressed and used for the following experiment.


An SH group of a half antibody (hereinafter referred to as “rIgG”) obtained by a reduction treatment of an antihuman CRP monoclonal antibody (mouse CRP-MCA (Oriental Yeast Co., Ltd.)) and an amino group included in each subunit protein of the above wild-type GDH were cross-linked with a cross-linker GMBS (Dojindo Molecular Technologies, Inc.) to prepare a CRP half antibody/GDH complex (rIgG-GDH).


The preparation procedure of the half antibody is shown in FIG. 4A, and the preparation procedure of the half antibody/GDH complex is shown in FIG. 4B, respectively.


The CRP binding ability of the obtained rIgG-GDH complex was examined by polyacrylamide gel electrophoresis and activity staining. The results are shown in FIG. 5. Comparing lane 18 (without CRP) and lane 21 (with CRP addition), the band near 800 kDa of lane 18 became thinner. This is conceivably because the molecular weight of the rIgG-GDH complex was shifted to the higher molecular weight site due to binding of CRP to the half antibody, which indicated that the rIgG-GDH complex was able to bind CRP.


The affinity of rIgG-GDH for CRP was examined using a protein-protein interaction analyzer BLItz from ForteBio. As a result, as shown in the table, it was confirmed that rIgG-GDH had the same affinity for CRP as CRP-MCA.














TABLE 3








KD (M)
ka (1/Ms)
kd (1/sec)









CRP-MCA
1.33.E−08
2.06.E+05
2.74.E−03



rIgG-GDH
1.08.E−08
5.23.E+04
5.67.E−04










Next, the above rIgG-GDH complex was immobilized on a printed carbon electrode (DEP Chip), the surface of which was modified with the SAM-forming molecule of 1-pyrenebutyric acid N-hydroxysuccinimide ester (PyNHS).


The procedure was as follows.










TABLE 4





Sensor strip used for



measurement
DEP-chip







Preparation of sensor
MWNT : 2% 0.4 μl × 2



20 min in McDry



+ 10 mM PyNHS 0.5 μl (in DMF)



20 min in McDry (remove DMF)



+ rIgG-GDH(Elution5), or CyGDH + rIgG(1:1)











2 mg/ml (50 mM TAPS pH 8.3) 2 μl









2 h in 25° C. under High RH



Store at Low Humidity (1% RH) until use









It was investigated whether direct electron transfer from the cytochrome c-containing subunit of GDH to the electrode occurred by a glucose oxidation reaction of GDH in the rIgG-GDH complex by adding glucose to react in a solution not containing a mediator using the obtained electrode with the immobilized rIgG-GDH complex.


As the control, a sensor, in which a mixed solution of equal amounts of rIgG and GDH (non-complex) was cast, was prepared and used. Each experiment was performed twice (n=2).


The experimental procedure was as follows.









TABLE 5







Electrochemical Measurement


Electrode chips: DEP-chip (EP-P)


Uniscan multi-channel PG580RM


3-Electrode configuration;


  WE: Enzyme modified carbon (2.64 mm2)


 CE: carbon (DEP-chip)


 RE: Ag/AgCl (DEP-chip)


Cell volume: 2 mL


Test solution: PBS


Temperature: 25 ± 1° C.


Chronoamperometry: + 200 mV vs. Ag/AgCl


Measurement (1-1)  Sample: 0~600 mg/dL Glucose


Measurement (1-2) Sample: 300 mg/dL Glucose + 0~10 mg/dL CRP


Measurement (2-1) Sample: 0~600 mg/dL Glucose


Measurement (2-2) Sample: 10 mg/dL CRP + 0~600 mg/dL Glucose









The results are shown in FIG. 6.


The rIgG-GDH immobilized electrode exhibited a glucose concentration-dependent oxidation current, although the current value was lower than that of an electrode on which rIgG and GDH were immobilized without cross-linking. This suggests that the rIgG-GDH complex recruited into the vicinity of the electrode can transfer electrons generated by the catalytic activity of GDH to the electrode.


Example 3

A fusion protein (GDH-scFv) in which scFv (CRSC3) having affinity to human CRP is fused to the C-terminal of the electron-transferring subunit (β subunit) of a wild-type GDH derived from B. cepacia was prepared. The preparation procedure of the GDH-scFv fusion protein is shown in FIG. 7. The β subunit of GDH and the scFv are linked by a GGGGS linker (SEQ ID NO: 5), and the GDH-scFv fusion protein is denoted as GDH-scFv (GGGGS).


The CRP binding ability of the obtained GDH-scFv (GGGGS) was examined by polyacrylamide gel electrophoresis and activity staining. The results are shown in FIG. 8. Comparing lane 15 (without CRP) and lane 16 (with CRP addition), the bands of lane 16 for GDH-scFv moved to a higher molecular weight site by about +100 kDa (presence of multiple bands was conceivably due to formation of a multimer). This is conceivably because the molecular weight of the GDH-scFv (GGGGS) was shifted to the higher molecular weight site due to binding of CRP to scFv, which indicated that the GDH-scFv fusion protein was able to bind CRP.


Next, the above GDH-scFv (GGGGS) was immobilized on a carbon electrode (SPCE), the surface of which was modified with the SAM-forming molecule of 1-pyrenebutyric acid N-hydroxysuccinimide ester (PyNHS).


The procedure was as follows.










TABLE 6





Carbon electrode (SPCE)








2 % MWNT
*MWNT (MW-I,


SPCE: Spotted on CE (4.8 mm2)
MEIJO NANO


1.2 μL
CARBON CO., LTD.)


Dried out



1.0 μL of 10 mM PyNHS was spotted
*PyNHS in DMF


Dried out



3 μL of 0.5 mg/mL γαβ



+ CRP(0, 0.05, 0.25, 1 mg/mL)



or 3 μL of 0.6 mg/mL GDH-scFv(GGGGS)



+ CRP(0, 0.05, 0.25, 1 mg/mL)



or 3 μL of 0.6 mg/mL GDH-scFv(GGGGS)



+ BSA(0, 0.05, 0.25, 1 mg/mL)



spotted
* CRP is a sample subjected


50 mM PPB (pH 7.5)
to buffer change with PPB


2 h at 25° C. (high RH)



Dried out



GA vapor, 30 min at 25° C.



Store at Low Humidity (1% RH) until use









It was investigated whether direct electron transfer from the cytochrome c-containing subunit of GDH to the electrode occurred by a glucose oxidation reaction of GDH in the GDH-scFv (GGGGS) by adding glucose and CRP (0, 0.1, 0.5, or 2 mg/ml) to react in a solution not containing a mediator using the obtained electrode with the immobilized GDH-scFv (GGGGS).


The experimental procedure was as follows.










TABLE 7








3-Electrode configuration; SPCE



 WE: Enzyme modified carbon



 CE: Pt wire



 RE: Ag/AgCl (BAS RE-1B)



Cell volume: 2.0 mL



Temperature: 25 ± 1° C.



Equilibration (wash): 20 min in 50 mM Tris buffer



Stirring: ) rpm



Chronoamperometry:



 Potential: +400 mV vs. Ag/AgCl



 Duration: 5 min/1 conc.



 Stirring: 300 rpm



 Test sol.: 100 mM P.P.B. (pH 7.0)









The results are shown in FIG. 9.


The GDH-scFv (GGGGS) immobilized electrode exhibited a glucose concentration-dependent oxidation current. This suggests that GDH-scFv (GGGGS) recruited into the vicinity of the electrode can transfer electrons generated by the catalytic activity of GDH to the electrode. However, a CRP concentration-dependence was not exhibited.


While the invention has been described in detail with reference to preferred embodiments thereof, it will be apparent to one skilled in the art that various changes can be made, and equivalents employed, without departing from the scope of the invention. Each of the aforementioned documents as well as JP 2018-188675 is incorporated by reference herein in its entirety.

Claims
  • 1. A molecular recognition element comprising (i) a target molecule-recognizing portion, wherein the target molecule is an antigen and the target molecule-recognizing portion is an antibody against the antigen, and(ii) a direct electron transfer-type oxidoreductase linked to the target molecule-recognizing portion, wherein the oxidoreductase is a glucose dehydrogenase comprising a cytochrome-containing subunit of SEQ ID NO: 4.
  • 2. The molecular recognition element according to claim 1, wherein the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase are linked by a cross-linker.
  • 3. The molecular recognition element according to claim 1, wherein the molecular recognition element comprises a fusion protein of the target molecule-recognizing portion and the direct electron transfer-type oxidoreductase.
  • 4. The molecular recognition element according to claim 1, wherein the glucose dehydrogenase further comprises a catalytic subunit and a regulatory submit.
  • 5. A sensor comprising an electrode, and the molecular recognition element according to claim 1, immobilized on the electrode.
  • 6. The sensor according to claim 5, wherein the molecular recognition element is immobilized on the electrode by means of a monolayer forming molecule.
  • 7. A method for measuring a target molecule comprising introducing a sample containing a target molecule into the sensor according to claim 5; and detecting a signal based on the target molecule.
  • 8. A reagent for measuring a target molecule comprising the molecular recognition element according to claim 1.
Priority Claims (1)
Number Date Country Kind
JP2018-188675 Oct 2018 JP national
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Entry
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Related Publications (1)
Number Date Country
20200110080 A1 Apr 2020 US