JP2013124224A - Immunizing method for obtaining antibody of high antigen detection sensitivity - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for obtaining an antibody to be used in assaying a low-molecular-weight compound by an antigen-antibody reaction using a competition technique, with the antibody being higher in detection sensitivity to such a low-molecular-weight compound (antigen) compared to conventional antibodies.SOLUTION: The method for obtaining an antibody to such a low-molecular-weight compound is provided, comprising: immunizing an animal by using a plurality of low-molecular-weight compound-carrier protein conjugates each obtained by mutually coupling, via a linker, the corresponding low-molecular-weight compound and the corresponding carrier protein; wherein the linkers are different from each other.

Description

  The present invention relates to an animal immunization method for obtaining an antibody having high antigen detection sensitivity.

  Vertebrates have an immune system that protects them from disease. The immune system is a biological protection system that recognizes, attacks, and eliminates pathogens that have entered the body. What is important here is the discrimination between the living body itself (self) and other foreign substances (non-self). It is the antibodies that play a major role in this identification.

  Antibodies are mainly in the blood and circulate in the body along the bloodstream. When the pathogen enters the body, the antibody specifically recognizes and binds to a specific substance in the pathogen. At this time, a specific substance recognized by the antibody is called an antigen. The binding between the antibody and the antigen is performed by a mechanism corresponding to “key and keyhole”. That is, it is a mechanism that can bind only an antigen (key) that fits in an antigen binding site (keyhole) of an antibody. Therefore, it can be said that each three-dimensional structure is very important for the binding between the antibody and the antigen.

The specific interaction (binding) between the antibody and the antigen has a high affinity. For example, the dissociation constant (Kd) in the binding between a mouse monoclonal antibody and its antigen is 1 × 10 ⁻⁹ to 10 ⁻¹⁰ . This is so high that 96% or more of the antigen binds to the antibody when the antibody and the antigen are mixed at a concentration of 1M. Therefore, even if a very small amount of antigen enters the body, it can be captured by the antibody.

  As described above, the binding between an antibody and an antigen has major characteristics in terms of specificity and affinity. Therefore, the antibody can be said to be very useful as a tool for detecting a minute amount of a specific substance in a contaminant. Taking advantage of this, many products such as laboratory reagents, immunodiagnostic reagents and therapeutic drugs have been developed.

  Methods for detecting specific substances using antibodies have been studied very well and many reports have been made. However, focusing on the central part, it can be classified into several types. The most representative methods are the sandwich method and the competitive method. The sandwich method is a technique for capturing and detecting an antigen by sandwiching it between two types of antibodies. In this method, first, one antibody (primary antibody) is immobilized on a carrier, and the antigen is immobilized on the carrier by the action of the primary antibody. Next, another antibody (secondary antibody) labeled with an enzyme or a fluorescent dye is added. The labeled secondary antibody captures and binds to the antigen immobilized on the carrier. Then, the antigen is quantified by detecting a signal emitted by the labeled secondary antibody (FIG. 1). On the other hand, the competition method is a method for detecting an antigen using one kind of antibody. In this method, an antibody is immobilized on a carrier, and an antigen-containing sample and an antigen (labeled antigen) labeled with an enzyme or a fluorescent dye are added. As the amount of antigen in the sample increases, the labeled antigen that binds to the antibody decreases and the signal weakens. From the ratio of the signal emitted by the labeled antigen when the sample containing the antigen is added when the signal emitted by the labeled antigen when the sample not containing the antigen is 100%, the amount of antigen in the sample Is calculated (FIG. 2).

  The antigen can be quantitatively detected by either the sandwich method or the competitive method. However, there are advantages and disadvantages due to the difference in measurement principle. In the sandwich method, the amount of secondary antibody can be freely increased, so that the signal can be amplified. Therefore, even a very small amount of antigen can be detected with high sensitivity. However, since it is necessary to prepare two types of antibodies suitable for measurement, substances that can be detected by the sandwich method are limited to those having a plurality of sites that interact with antibodies and having a relatively large molecular weight. On the other hand, in the competitive method, only one type of antibody is used, and the experimental procedure is one step less than the sandwich method, so the measurement time is short, and the low molecular weight compound has few sites that interact with the antibody (Non-patent Document 1). Can also detect antigen quantitatively. However, since the signal cannot be amplified as in the sandwich method, the sensitivity is inferior to that of the sandwich method when antibodies having the same performance are used.

Biochemistry, 82 (8), 710: 2010

  As described above, since a low molecular weight compound has few sites that interact with an antibody, in order to quantify the compound using an antigen-antibody reaction, measurement by a competitive method is used instead of the sandwich method. However, compared with the sandwich method, it was difficult for the competitive method to detect a low molecular weight compound as an antigen with high sensitivity. In order to obtain antibodies that detect low molecular weight compounds with high sensitivity, it is usually attempted to immunize multiple animals at the same time and select the antibody with the best performance. Whether or not it is possible to obtain an antibody having an antibody depends on luck, and as a result, there have been problems such as sacrificing the lives of many animals.

  In order to solve the above problems, many studies have been conducted on the amount of antigen and type of adjuvant used for immunization. However, until now, no method has been found to solve the above problem.

  The present invention aims to solve the above problems. That is, the problem to be solved by the present invention is a method for obtaining an antibody to be used for measurement of a low molecular weight compound by an antigen-antibody reaction using a competition method, which is directed to the low molecular weight compound (antigen) from a conventional antibody. The present invention provides a method for obtaining an antibody with high detection sensitivity.

  This invention made | formed in view of the said subject includes the following aspects.

That is, the first aspect of the present invention is:
A method of obtaining an antibody against the low molecular weight compound by immunizing an animal using a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker,
In the above method, an animal is immunized with a plurality of low molecular weight compound-carrier protein complexes having different linkers.

The second aspect of the present invention is as follows.
A plurality of low molecular weight compound-carrier protein complexes having different linkers,
A first low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a first linker, and a low molecular weight compound and a carrier protein via a second linker A second low molecular weight compound-carrier protein complex obtained by binding,
First immunizing the animal continuously with the first low molecular weight compound-carrier protein complex, then immunizing the animal continuously with the second low molecular weight compound-carrier protein complex, A method according to an embodiment.

  The third aspect of the present invention is the method according to the first or second aspect, wherein the low molecular weight compound and the linker have the same binding position in the plurality of low molecular weight compound-carrier protein complexes. is there.

  A fourth aspect of the present invention is the method according to any one of the first to third aspects, wherein the low molecular weight compound is a steroid hormone.

  In the fifth aspect of the present invention, the steroid hormone is progesterone, and the binding position of the progesterone and the linker in the plurality of low molecular weight compound-carrier protein complexes is the carbon atom at the 11th position of progesterone. The method according to the fourth aspect.

Furthermore, the sixth aspect of the present invention provides
An antibody obtained by immunizing an animal with a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker;
A low molecular weight compound bound to a labeling substance via a linker;
A reagent for measuring the low molecular weight compound, the antibody comprising:
The measurement reagent, which is an antibody obtained by immunizing an animal using a plurality of low molecular weight compound-carrier protein complexes having different linkers.

  According to a seventh aspect of the present invention, in the one of the plurality of low molecular weight compound-carrier protein complexes, the linker through the bond between the low molecular weight compound and the carrier protein comprises a labeling substance and a low molecular weight compound. The reagent according to the sixth aspect, which is the same as a linker through a bond.

  Hereinafter, the present invention will be described in detail.

  When obtaining an antibody against a low molecular weight compound, the compound has few sites that interact with the antibody due to its small size. Therefore, even if an animal is immunized with the compound alone, its immunogenicity is low and it is difficult to obtain an antibody against the compound. Therefore, an animal is immunized in the form of a low molecular weight compound-carrier protein complex in which a carrier protein such as bovine serum albumin (BSA) is bound to the compound via a linker (Non-patent Document 1). As a result, immunogenicity is exhibited, and an antibody against the compound can be obtained.

  When detecting the said compound using the antibody with respect to a low molecular weight compound, a competition method is usually used. In that case, it is important to note that when preparing a low molecular weight compound-carrier protein complex and a low molecular weight compound (labeled antigen) bound to a labeling substance, the low molecular weight compound and carrier protein (or labeling substance) Linker between In order for the low molecular weight compound (antigen) and the antibody against the compound to interact (bond), the steric structure of each other is important. Therefore, when producing the complex and the labeled antigen, the linker structure and the binding position of the low molecular weight compound and the linker are usually the same. The reason for this is that when the linker structure is made different from each other and / or the binding position of the low molecular weight compound and the linker is made different from each other, the site of the low molecular weight compound that interacts with the antibody against the compound can be reduced. This is because it may be hidden, and as a result, it may interfere with the recognition of the compound by the antibody.

  However, as a result of intensive studies by the present inventors, two or more (plural) low molecular weight compound-carrier protein complexes are prepared, and animals are immunized using the two or more (plural) complexes. It has been found that the detection sensitivity of the compound is improved as compared with the antibody obtained by immunizing an animal with one kind of low molecular weight compound-carrier protein complex. In addition, it is preferable that the bonding positions of the low molecular weight compound and the linker in the plurality of low molecular weight compound-carrier protein complexes are the same. The reason is that if the binding position of the low molecular weight compound and the linker in the plurality of complexes is different, the site of the low molecular weight compound that interacts with the antibody against the compound may be hidden.

As a specific example of the antibody obtaining method of the present invention,
A first low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a first linker;
A second low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a second linker;
First, the animal is continuously immunized with the first low molecular weight compound-carrier protein complex, and then the animal is continuously immunized with the second low molecular weight compound-carrier protein complex to thereby reduce the low molecular weight. And a method for obtaining an antibody against the compound. In the specific example, the first linker used for obtaining the first low molecular weight compound-carrier protein complex has the same structure as the linker used for obtaining the labeled antigen, and in the first complex The binding position between the low molecular weight compound and the linker is preferably the same position as the binding position between the low molecular weight compound and the linker in the labeled antigen. In the specific example, the timing of switching from immunization using the first low molecular weight compound-carrier protein complex to immunization using the second low molecular weight compound-carrier protein complex is the first low molecular weight compound- It may be performed when the performance (antigen detection sensitivity) of the antibody obtained by immunization using the carrier protein complex is no longer improved, or when the degree of improvement is low. By switching the low molecular weight compound-carrier protein complex that immunizes the animal, a change occurs in the structure of the low molecular weight compound exposed to the outside in the complex. Therefore, the recognition site of the low molecular weight compound in the antibody obtained by immunizing the animal using the complex after switching changes from the recognition site in the antibody obtained by immunizing the animal using the complex before switching. That is, an antibody obtained by immunizing an animal using the complex after switching has a lower affinity for the labeled antigen than an antibody obtained by immunizing the animal using the complex before switching, The affinity with the labeled antigen is relatively increased. Thereby, the sensitivity which detects a low molecular weight compound (antigen) improves. As an example of the continuous immunization method using the low molecular weight compound-carrier protein complex in the specific example, a mixture of the complex and an appropriate adjuvant is used every 1 to 2 weeks for 1 to 12 months. In the meantime, there is a method of immunizing animals.

  In the present invention, examples of animals that immunize a low molecular weight compound-carrier protein complex include mice, rats, rabbits, chickens, and goats that are commonly used by those skilled in the art.

  The target antigen (low molecular weight compound) of the antibody that can be obtained by the method of the present invention may be an antigen having at least one site capable of binding to a linker. Examples thereof include triiodothyronine (T3), thyroxine (T4). ), Thyroid hormones such as 3,5-diiodo-L-thyronine (T2), and steroid skeletons such as estrone (E1), estradiol (E2), estriol (E3), progesterone, cortisol and the like. Examples include steroid hormones. Among them, steroid hormones are preferable as target antigens (low molecular weight compounds) for antibodies obtained by the method of the present invention because of the large number of sites that can bind to a linker.

  The linker used in the method of the present invention through the bond between the low molecular weight compound and the carrier protein is not particularly limited as long as it does not completely impair the interaction between the obtained antibody and the labeled antigen. NHS (N-Hydroxysuccinimide) compounds that are reactive with amino groups are often used because of their ease and low cost. Other linkers include compounds reactive with amino groups such as imide ester compounds, compounds reactive with carboxyl groups such as carbodiimide compounds, and compounds reactive with thiol groups such as maleimide compounds, haloacetyl compounds, and pyridylacetyl compounds. Is available as Furthermore, as the low molecular weight compound-carrier protein complex, a complex in which a low molecular weight compound and a carrier protein are bound by a non-covalent bond having a high affinity such as an avidin-biotin bond may be used.

  The carrier protein that is used in the method of the present invention and binds to a low molecular weight compound via a linker is not particularly limited as long as it is a protein having a molecular weight of about 10 kDa or more. For example, fluorescent proteins such as Protein), YFP (Yellow Fluorescent Protein), and RFP (Red Fluorescent Protein), and bacteria-derived heat shock proteins (Heat Shock Protein) such as DnaK, DnaJ, GroEL, GroES, and ClpB can be used. Usually, however, BSA (Bovine Serum Albumin), BCP (Blue Carrier Protein), KLH (Keyhole Limit Hemocyanin), OVA (Ovalbumin), etc. are used as carrier proteins because of their availability and low price.

  The antibody obtaining method of the present invention is directed to the low molecular weight compound by immunizing an animal using a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker. When an antibody is obtained, an animal is immunized using a plurality of low molecular weight compound-carrier protein complexes having different linkers. The antibody obtained by the method of the present invention has improved detection sensitivity for the compound as compared with the conventional antibody. Therefore, the compound can be measured with higher sensitivity by adopting the antibody obtained by the method of the present invention as a reagent for measuring a low molecular weight compound utilizing an antigen-antibody reaction.

The figure which showed the measurement principle of the sandwich method. The figure which showed the measurement principle of the competition method. FIG. 3 shows progesterone derivatives (Prog A, Prog B) prepared in Example 1. The figure which shows the performance (antigen detection sensitivity) change of the antibody obtained by immunization by Example 3. FIG. The figure which shows the result of having evaluated the antigen detection sensitivity of the antibody obtained by blood-collecting in the 9th month and the 10th month of the immunization start.

  Hereinafter, the present invention will be described in more detail by taking a progesterone measuring reagent using a rabbit anti-progesterone antibody as an example, but the present invention is not limited to these examples.

Example 1 Production of Antigen Complex A progesterone-BSA complex was prepared by the method shown below.
(1) In order to obtain an anti-progesterone rabbit antibody, two types of derivatives in which a linker was bonded to the carbon atom at the 11th position of progesterone were produced (FIG. 3). A derivative (11α- (4-NHS-1,4-dioxo-1-oxybutane) -progesterone) prepared using 4-NHS-1,4-dioxo-1-oxybutane as a linker is hereinafter referred to as Prog A, and as a linker. 2-Carbonyl (4-NHS-4-oxo-1-aminobutane) Derivative (11α- [2-carbonyl (4-NHS-4-oxo-1-aminobutane) -1-oxycarbynecylcyclone) produced using 1-oxycarbonylcyclohexane ] -Progesterone) is hereinafter referred to as Prog B.
(2) After 3.5 mg of the derivatives (Prog A, Prog B) prepared in (1) were dissolved in 50 μL of DMSO, BSA solution (25 mg of BSA as a carrier protein was added to 50 mM borate buffer (pH 8.5) 2 Solution obtained by dissolving in 5 mL) was gradually added with stirring and allowed to react at room temperature for 30 minutes.
(3) The reaction solution was put into a dialysis membrane having a fractional molecular weight of 10 kDa, and unreacted derivatives were removed by dialysis three times at 4 ° C. in 1 L of PBS (Phosphate Buffered Saline). After dialysis, progesterone-BSA (Prog A-BSA or Prog B-BSA) complex was recovered from the dialysis membrane and used for immunization of rabbits.

Example 2 Production of Labeled Antigen (CJ) Using alkaline phosphatase (ALP) and Prog A, a labeled antigen (CJ) was prepared by the following method.
(1) 5 mg of ALP was put into a dialysis membrane having a fractional molecular weight of 10 kDa, and dialyzed three times at 4 ° C. in 500 mL of 50 mM borate buffer (pH 9.0). To the dialyzed ALP solution, 10 μL of a DMSO solution obtained by dissolving 1 mg of Prog A in 540 μL of DMSO was added and reacted at 4 ° C. overnight.
(2) The reaction solution was put into a dialysis membrane having a fractional molecular weight of 10 kDa, and dialyzed 3 times at 4 ° C. in 1 L of 5 mM sodium phosphate buffer (pH 7.0) to remove unreacted Prog A. After dialysis, the liquid in the dialysis membrane was collected and applied to a DEAE column equilibrated with 5 mM sodium phosphate buffer (pH 7.0).
(3) After washing the applied column with a washing buffer (5 mM sodium phosphate buffer (pH 7.0), 20 mM NaCl), an elution buffer (5 mM sodium phosphate buffer (pH 7.0), 100 mM NaCl) is applied. As a result, CJ was eluted from the column and purified.
(4) The purified CJ is put into a dialysis membrane having a fractional molecular weight of 10 kDa, and 1 L storage buffer (25 mM Tris-HCl (pH 7.5), 5 mM MgCl ₂ , 0.1 mM ZnCl ₂ , 0.1% NaN ₃ ) Was dialyzed 3 times at 4 ° C. After dialysis, CJ (Prog A-ALP) was recovered from the dialysis membrane and used in the following examples.

Example 3 Immunization of Rabbit Using the antigen complex prepared in Example 1, rabbits were immunized by the following method.
(1) First, a Japanese white female rabbit was prepared. When the rabbit was 12 weeks old, it was immunized with a mixture of equal amounts of 0.5 mg of Prog A-BSA complex and Freund's complete adjuvant. Thereafter, an equal amount of 0.25 mg of Prog A-BSA complex and incomplete Freund's adjuvant was immunized every week.
(2) After the start of immunization, a small amount of blood was collected every month, serum was prepared, and the progress of immunization (antibody performance) was examined by the method described later (method described in Example 4).
(3) When the improvement in the performance (antigen detection sensitivity) of antibodies obtained by immunization has slowed, the immunization method was changed. First, 8 months after the start of immunization, the amount of antigen used for immunization was increased from 0.25 mg / dose to 0.5 mg / dose, and immunization was performed every week for 1 month. Next, 9 months after the start of immunization, the adjuvant used for immunization was changed from Freund's incomplete adjuvant to Freund's complete adjuvant, and 0.5 mg was immunized every week for 1 month. At 10 months after the start of immunization, the antigen complex was changed from Prog A-BSA complex to Prog B-BSA complex, and the adjuvant used for immunization was changed from Freund's complete adjuvant to Freund's incomplete adjuvant for 1 week. Immunization was performed at 0.5 mg each for 1 month. The antibody obtained by immunization was collected at the end of each step, and after the serum was prepared, the antibody performance (antigen detection sensitivity) was followed up by the method described later (method described in Example 4). .

Example 4 Follow-up of Immunization Follow-up was performed by examining changes in the performance (antigen detection sensitivity) of antibodies obtained by immunization of rabbits according to Example 3 by the following method. This operation was performed fully automatically at 37 ° C. using an enzyme immunoassay device AIA-600II manufactured by Tosoh Corporation.
(1) CJ (Prog A-ALP) produced in Example 2 was mixed with magnetic particles on which an anti-rabbit IgG antibody was immobilized.
(2) A calibrator solution with a known progesterone concentration (Cal6: 45.4 ng / mL, manufactured by Tosoh Corporation) was prepared, and a certain amount was added to the mixture of (1).
(3) The antiserum obtained by immunization according to Example 3 was added to (2) and reacted for 10 minutes.
(4) After the reaction, B / F (Bound / Free) separation was performed, and after adding an ALP substrate, a fluorescent signal emitted from CJ bound to the magnetic particles was detected.
(5) The signal (B) when Cal6 is added when the signal (B0) when the calibrator (Cal1) containing no progesterone is added is 100% is a relative value (B / B0 [% ]). The lower this B / B0 is, the higher the affinity of the antibody for the antigen is. That is, the lower the B / B0 value, the higher the antigen detection sensitivity of the obtained antibody.

  The results of examining changes in the performance (antigen detection sensitivity) of the antibody obtained by immunization according to Example 3 are shown in FIG. It can be seen that at the beginning of immunization, the B / B0 value is steadily decreasing, and the antibody performance (antigen detection sensitivity) is steadily improving. However, after 6 months from the start of immunization, the decrease in the B / B0 value becomes slight, indicating that the improvement in antibody performance (antigen detection sensitivity) is slow. Therefore, the amount of antigen used for immunization was changed 8 months after the start of immunization, and the adjuvant used for immunization was changed 9 months after the start of immunization, but there was almost no change in the B / B0 value, and the antibody performance (Antigen detection sensitivity) was not improved. However, when the antigen used for immunization was changed from Prog A-BSA complex to Prog B-BSA complex 10 months after the start of immunization, the B / B0 value decreased again, and the antibody performance (antigen detection) (Sensitivity) improved.

Example 5 Quantitative evaluation of antibody performance (antigen detection sensitivity) The antigen detection sensitivity of the antibody obtained by immunization according to Example 3 was quantitatively evaluated by the following method. This operation was performed fully automatically at 37 ° C. using an enzyme immunoassay device AIA-600II manufactured by Tosoh Corporation.
(1) CJ (Prog A-ALP) produced in Example 2 was mixed with magnetic particles on which an anti-rabbit IgG antibody was immobilized.
(2) Calibrator solutions with known progesterone concentrations (Cal2 to Cal6, manufactured by Tosoh Corporation) were prepared, and each was added in a certain amount to the mixture of (1).
(3) The antiserum obtained by immunization according to Example 3 was added to (2) and reacted for 10 minutes.
(4) After the reaction, B / F separation was performed, and after adding an ALP substrate, a fluorescent signal emitted from CJ bound to the magnetic particles was detected.
(5) Relative value of signal (B) when each calibrator (Cal2 to Cal6) is added, assuming that signal (B0) when adding calibrator (Cal1) containing no progesterone is 100% Calculated as (B / B0 [%]). A calibration curve was prepared by plotting the measurement results when using each calibrator with the progesterone concentration on the horizontal axis (logarithm) and B / B0 (%) on the vertical axis.
(6) Using the progesterone concentration (C50) when B / B0 = 50% as an index, the antigen detection sensitivity of the obtained antibody was quantitatively evaluated.

  The experimental results are shown in FIG. Changing the antigen used for immunization from Prog A-BSA complex (antibody obtained by blood collection 9 months after immunization) to Prog B-BSA complex (antibody obtained by blood collection 10 months after immunization) Thus, C50 is changed from 7.3 ng / mL (antibody obtained at 9 months after immunization) to 5.8 ng / mL (antibody obtained at 10 months after immunization), and detection sensitivity is improved. (Figure 5). That is, when an antibody against the low molecular weight compound is obtained by immunizing an animal using a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker, The performance (antigen detection sensitivity) of the obtained antibody can be further improved by preparing a plurality of low molecular weight compound-carrier protein complexes having different linkers and immunizing an animal using the plurality of complexes.

Claims (7)

A method of obtaining an antibody against the low molecular weight compound by immunizing an animal using a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker,
The method, wherein the animal is immunized with a plurality of low molecular weight compound-carrier protein complexes having different linkers. A plurality of low molecular weight compound-carrier protein complexes having different linkers,
A first low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a first linker, and a low molecular weight compound and a carrier protein via a second linker A second low molecular weight compound-carrier protein complex obtained by binding,
The animal according to claim 1, wherein the animal is continuously immunized first with the first low molecular weight compound-carrier protein complex and then continuously immunized with the second low molecular weight compound-carrier protein complex. The method described. The method according to claim 1 or 2, wherein the bonding positions of the low molecular weight compound and the linker in the plurality of low molecular weight compound-carrier protein complexes are the same. The method according to any one of claims 1 to 3, wherein the low molecular weight compound is a steroid hormone. The method according to claim 4, wherein the steroid hormone is progesterone, and the binding position of the progesterone and the linker in the plurality of low molecular weight compound-carrier protein complexes is the carbon atom at the 11th position of progesterone. An antibody obtained by immunizing an animal with a low molecular weight compound-carrier protein complex obtained by binding a low molecular weight compound and a carrier protein via a linker;
A low molecular weight compound bound to a labeling substance via a linker;
A reagent for measuring the low molecular weight compound, the antibody comprising:
The measurement reagent, which is an antibody obtained by immunizing an animal using a plurality of low molecular weight compound-carrier protein complexes having different linkers. The linker through the bond between the low molecular weight compound and the carrier protein in one of the plurality of low molecular weight compound-carrier protein complexes is the same as the linker through the bond between the labeling substance and the low molecular weight compound. Item 7. The reagent according to Item 6.

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