JP6253529B2 - Search method for fatigue inhibitors - Google Patents

Description

  The present invention relates to a method for searching for a fatigue inhibitor.

In modern society, fatigue is prevalent due to overwork and stress. For example, according to the results of a survey on the actual situation of fatigue conducted in Japan in 1999 (Head of the Ministry of Health and Welfare Research Group: Teruo Kitani, Osaka University), out of 4,000 general residents in the Nagoya area (number of valid responses: 3,015), It has been clarified that 59.1% of people are aware of fatigue, and that 35.8% of people have chronic fatigue that lasts more than half a year (Non-Patent Document 1).
Under such circumstances, the development of anti-fatigue materials is desired, and in recent years, the expression of Fos-like protein in rats in which the “green scent” released by fresh green leaves has expressed Fos-like protein due to restraint stress. (Non-patent Document 2), and further, the scent of a mixture of trans-2-hexenal and cis-3-hexenol (hereinafter referred to as “trans-2-hexenal / cis-3-hexenol mixture”) is fatigued. It has been reported to have a recovery effect (Patent Document 1).

Fatigue can be defined as a state in which work efficiency (performance) is temporarily lowered when a load is applied to the mind or body. For this reason, in the development of anti-fatigue materials, it is recommended not only to evaluate VAS (Visual Analogue Scale), which is a subjective fatigue evaluation, but also to perform performance (working efficiency) evaluation based on workload (non-patented) Reference 3).
Therefore, these evaluations have a problem that many materials cannot be evaluated at a time because it is necessary to evaluate the effect after applying a certain amount of fatigue to the subject.

Japanese Patent No. 4422103

Teruo Kitani. Research on the actual state of fatigue and methods for recovery from fatigue for health promotion (Ministry of Health and Welfare). 1999 research results report. 2000. Abstract of the 76th Annual Meeting of the Physiological Society of Japan, 258, 1999 Fatigue Society Anti-Fatigue Clinical Evaluation Guidelines

  The present invention provides a method for efficiently searching for fatigue inhibitors or candidate substances thereof.

In mammals such as humans, the smell is bound to the olfactory receptor on the olfactory nerve cell located in the olfactory epithelium in the upper nasal cavity, and the response of the receptor is transmitted to the central nervous system. It is recognized by. In recent years, a method has been developed to functionally express olfactory receptors in cultured cells and to individually observe the activity of the receptors (Katada et al, Biochem Biophys Res Commun 2003, 305: 964-969). Methods for searching for ligands of the olfactory receptor using cultured cells that express the body are known (International Publication No. 2006/002161, International Publication No. 2008/008224).
The present inventor has succeeded in newly identifying an olfactory receptor that responds to the scent of the trans-2-hexenal / cis-3-hexenol mixture having the above-described fatigue recovery effect, and has selected a specific one selected from the olfactory receptors. It has been found that a fatigue inhibitor or a candidate substance thereof can be evaluated and selected by using the response of an olfactory receptor as an index.

That is, this invention relates to the search method of the fatigue inhibitor or its candidate substance including the following process a) -c).
a) adding a test substance to an olfactory receptor polypeptide comprising OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 b) measuring a response of the receptor polypeptide to the test substance c) a measured response Selecting a test substance that enhances the response as a fatigue inhibitor or a candidate substance thereof based on

  ADVANTAGE OF THE INVENTION According to this invention, a fatigue inhibitor or its candidate substance can be searched simply and efficiently.

Response of olfactory receptors to the scent of a trans-2-hexenal / cis-3-hexenol mixture. The horizontal axis represents individual olfactory receptors, and the vertical axis represents response intensity. Response of each olfactory receptor to various concentrations of fragrance composition. Error bar = ± SE. Fatigue inhibiting effect of the fragrance composition.

In the present invention, “fatigue” means a temporary physical and mental performance degradation phenomenon that occurs when a physical or mental load is continuously applied. Shows qualitative or quantitative decline in physical and mental work ability. And "fatigue suppression" means the effect | action which attenuates the said fatigue and the effect | action which recovers fatigue.
Further, “fatigue” of the present invention includes chronic fatigue syndrome (CFS) and death from overwork.
Chronic fatigue syndrome is known as a pathological condition in which a healthy social life cannot be sent due to chronic fatigue of unknown cause (Journal of the Japan Society for Internal Medicine, 81: 573-582 (1992)), and its basic symptoms Examples include severe general malaise with unknown cause, slight fever, headache, lymphadenopathy, muscle pain, weakness, disorder related to thinking or concentration, depressive symptoms, and sleep disorders.
Overworked death is a severe overworked state that, despite being unable to maintain physical vitality, is unable to feel fatigue enough, resulting in cerebrovascular disease and heart disease and becoming permanent It means a state where work has become impossible or fatal.
Therefore, the fatigue inhibitor of the present invention includes alleviating each symptom of such chronic fatigue syndrome and shifting to a normal state, and thereby preventing overwork death.

  In the present invention, `` olfactory receptor polypeptide '' refers to an olfactory receptor or a polypeptide having a function equivalent thereto, and a polypeptide having a function equivalent to an olfactory receptor is similar to an olfactory receptor, A polypeptide that can be expressed on the cell membrane and is activated by the binding of odor molecules (Nat. Neurosci. 2004, 5: 263-278).

  In the present specification, nucleotide sequence and amino acid sequence identity is calculated by the Lippman-Pearson method (Lipman-Pearson method; Science, 1985, 227: 1435-41). Specifically, using the homology analysis (Search homology) program of genetic information software Genetyx-Win (Ver. 5.1.1; software development), analysis is performed with Unit size to compare (ktup) as 2. Is calculated by

  The method of searching for a fatigue inhibitor or candidate substance thereof according to the present invention comprises: a) a step of adding a test substance to an olfactory receptor polypeptide comprising OR1A1, OR2J3, OR2W1, OR5K1, OR5P3, and OR10A6, b) the test substance for the test substance Measuring the response of the receptor polypeptide, c) selecting a test substance that enhances the response as a fatigue inhibitor or a candidate substance based on the measured response.

In the method of the present invention, OR1A1, OR2J3, OR2W1, OR5K1, OR5P3, and OR10A6 are all olfactory receptors expressed in human olfactory cells.
OR1A1 is registered in GenBank as GI: 289547622. OR1A1 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 2 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 1.
OR2J3 is registered with GenBank as GI: 5075888245. OR2J3 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 4 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 3.
OR2W1 is registered with GenBank as GI: 16234788. OR2W1 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 6 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 5.
OR5K1 is registered in GenBank as GI: 115270954. OR5K1 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 8 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 7.
OR5P3 is registered in GenBank as GI: 23592229. OR5P3 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 10 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 9.
OR10A6 is registered as GI: 52218835 in GenBank. OR10A6 is a protein consisting of an amino acid sequence represented by SEQ ID NO: 12 encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 11.
As shown in FIG. 1, the olfactory receptor polypeptide containing OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 is known to have a fatigue recovery effect trans-2-hexenal / cis-3-hexenol. It was clarified to show a response to the scent of the mixture.
Therefore, the polypeptide functionally equivalent to the six olfactory receptors OR1A1, OR2J3, OR2W1, OR5K1, OR5P3, and OR10A6 is the olfactory receptor polypeptide in the same manner as the six olfactory receptors. Can be used for As such an olfactory receptor polypeptide, for example, 80% or more, preferably 85% or more, more preferably 90% or more, further preferably, with respect to each amino acid of OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6. A polypeptide having an amino acid sequence having a sequence identity of 95% or more, preferably 98% or more, and having responsiveness to a trans-2-hexenal / cis-3-hexenol mixture can be mentioned.
Here, the mixing ratio of cis-3-hexenol and trans-2-hexenal is not particularly limited, but is preferably an equimolar mixture.

  In the method of the present invention, the olfactory receptor polypeptide can be used in any form as long as the function of the receptor is not lost. For example, an olfactory receptor polypeptide is a tissue or cell that naturally expresses an olfactory receptor polypeptide, such as an olfactory receptor or olfactory cell isolated from a living body, or a culture thereof; A supported olfactory cell membrane; a recombinant cell or culture thereof genetically engineered to express the olfactory receptor polypeptide; a membrane of the recombinant cell; and an artificial having the olfactory receptor polypeptide It can be used in the form of a lipid bilayer, etc. All of these forms fall within the scope of the olfactory receptor polypeptide used in the present invention.

  In a preferred embodiment, cells that naturally express olfactory receptor polypeptides such as olfactory cells, recombinant cells genetically engineered to express olfactory receptor polypeptides, or cultures thereof are used. The The recombinant cell can be produced by transforming the cell using a vector incorporating a gene encoding an olfactory receptor polypeptide.

Preferably, in order to promote cell membrane expression of the olfactory receptor polypeptide, a gene encoding RTP (receptor-transporting protein) is introduced into the cell together with the gene encoding the olfactory receptor polypeptide. Preferably, a gene encoding RTP1S is introduced into a cell together with a gene encoding the olfactory receptor polypeptide. An example of RTP1S includes human RTP1S. Human RTP1S is a protein consisting of the amino acid sequence represented by SEQ ID NO: 14, which is registered in GenBank as GI: 50234917 and is encoded by a gene having a nucleotide sequence represented by SEQ ID NO: 13.
Further, instead of human RTP1S, the amino acid sequence of human RTP1S (SEQ ID NO: 14) is 80% or more, preferably 85% or more, more preferably 90% or more, still more preferably 95% or more, and still more preferably 98%. A polypeptide that has an amino acid sequence having a sequence identity of at least% and promotes the expression of the olfactory receptor membrane in the same manner as human RTP1S may be used.

  The test substance used in the method of the present invention is not particularly limited as long as it is a substance desired to be used as a fatigue inhibitor. The test substance may be a naturally occurring substance, a substance artificially synthesized by a chemical or biological method, etc., and may be a compound, a composition or a mixture. Good.

After adding the test substance, the response of the olfactory receptor polypeptide is measured.
The measurement may be performed by any method known in the art as a method for measuring the response of the olfactory receptor, such as a calcium imaging method. In addition, when activated by odor molecules, olfactory receptors are known to increase the amount of intracellular cAMP by activating adenylate cyclase in combination with intracellular Gαs (Touhara K. Neurochem Int. 2007 51. 132-139.). Therefore, for example, the response of the olfactory receptor can be measured by using the amount of intracellular cAMP after adding the test substance as an index. Examples of the method for measuring the amount of cAMP include an ELISA method and a reporter gene assay method.

  Next, based on the measured response of the olfactory receptor polypeptide, a test substance that responds to the receptor polypeptide is identified. The test substance can be identified by comparing the response of the olfactory receptor polypeptide to which the test substance is added with the response of the olfactory receptor polypeptide to which the test substance is not added. Alternatively, the response of the olfactory receptor polypeptide to which a test substance is added can be compared with the response of a cell that does not express the olfactory receptor polypeptide to which a test substance is added. Alternatively, the response of the olfactory receptor polypeptide added with the test substance can be compared with the response of the olfactory receptor polypeptide before the test substance is added. Alternatively, the response of the olfactory receptor polypeptide to which a test substance and a control substance are added can be compared with the response of the olfactory receptor polypeptide to which a control substance is added.

  For example, the effect of the test substance on the response of the olfactory receptor polypeptide is that the test substance is added between the test substance addition group and the non-addition group, between the olfactory receptor polypeptide expression group and the non-expression group, It can be evaluated by comparing the response of the olfactory receptor polypeptide before and after the addition, or between the test substance and the control substance group. When the response of the olfactory receptor polypeptide is activated by the addition of the test substance, the test substance can be identified as a substance that activates or enhances the response of the olfactory receptor polypeptide. Examples of the control substance include a trans-2-hexenal / cis-3-hexenol mixture.

The test substance identified by the above procedure activates six types of olfactory receptors, OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6, as shown in Examples below (FIG. 2), and is a known fatigue inhibitor. A fatigue suppression effect equal to or greater than that of the trans-2-hexenal / cis-3-hexenol mixture is observed (FIG. 3). Therefore, the test substance can be a fatigue inhibitor or a candidate substance thereof.
For example, the response of the olfactory receptor polypeptide in the test substance addition group measured by the above procedure is preferably 1.1 times or more, more preferably 1.2 times or more, even more preferably compared to the control group. Is 1.5 times or more, the test substance can be evaluated or selected as a fatigue inhibitor or a candidate substance thereof. Alternatively, if the response of the olfactory receptor polypeptide in the test substance addition group measured by the above procedure is statistically significantly higher than that of the control group, the test substance is added to the fatigue inhibitor or its Can be evaluated or selected as a candidate substance.

  Thus, the test substance evaluated or selected can be used as a fatigue inhibitor or a candidate substance thereof, and can be used to produce a fatigue inhibitor or a candidate substance thereof. Candidate substances for fatigue inhibitors are fatigue inhibitors by performing a known fatigue assessment, such as behavioral tests to evaluate work efficiency for personal computer work, autonomic function measurement, salivary cortisol measurement, etc., as necessary. Can be selected.

With respect to the above-described embodiment, the following aspects are further disclosed in the present invention.
<1> A search method for a fatigue inhibitor or a candidate substance thereof comprising the following steps a) to c).
a) adding a test substance to an olfactory receptor polypeptide comprising OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 b) measuring a response of the receptor polypeptide to the test substance c) a measured response A step of selecting a test substance that enhances the response as a fatigue inhibitor or a candidate substance thereof based on the above <2> on a cell in which the olfactory receptor polypeptide naturally expresses the olfactory receptor polypeptide or an olfactory receptor <1> The method of <1>, wherein the olfactory receptor is expressed on a recombinant cell genetically engineered to express the polypeptide.
<3> The method according to <1> or <2>, further comprising a step of measuring a response of an olfactory receptor polypeptide to which no test substance is added.
<4> If the response of the olfactory receptor to which the test substance is added is 1.1 times or more than the response of the olfactory receptor to which the test substance is not added, the test substance is added to the fatigue inhibitor or <3> The method of selecting as a candidate substance.
<5> The method according to any one of <1> to <4>, wherein the step of measuring the receptor response is performed by a reporter gene assay.

EXAMPLES Hereinafter, an Example is shown and this invention is demonstrated more concretely.
Example 1 Identification of Olfactory Receptor Responsive to Fragrance of Trans-2-Hexenal / Cis-3-hexenol Mixture (1) Cloning of Human Olfactory Receptor Gene Human olfactory receptor is based on sequence information registered in GenBank. Then, cloning was performed by PCR using human genomic DNA female (G1521: Promega) as a template. Each gene amplified by the PCR method is incorporated into a pENTR vector (Invitrogen) according to the manual, and the Not I and Asc I sites existing on the pENTR vector are used to create a Not generated downstream of the Flag-Rho tag sequence on the pME18S vector. I, recombined into the Asc I site.

(2) Preparation of pME18S-RTP1S vector Human RTP1S was cloned by the PCR method using human RTP1 gene (MHS1010-9205862: Open Biosystems) as a template. In the primer used for PCR, EcoR I was added to the sense side and Xho I site was added to the antisense side. The hRTP1S gene (SEQ ID NO: 13) amplified by the PCR method was incorporated into the EcoR I and Xho I sites of the pME18S vector.

(3) Preparation of olfactory receptor-expressing cells HEK293 cells each expressing 396 kinds of human olfactory receptors were prepared. A reaction solution having the composition shown in Table 1 was prepared and allowed to stand in a clean bench for 15 minutes, and then added to each well of a 96-well plate (BD). Next, 100 μl of HEK293 cells (3 × 10 ⁵ cells / cm ² ) were seeded in each well and cultured for 24 hours in an incubator maintained at 37 ° C. and 5% CO ² .

(4) Preparation of trans-2-hexenal / cis-3-hexenol mixture cis-3-hexenol (3-hexen-1-ol: Sigma-Aldrich) and trans-2-hexenal (2-hexenal: Sigma-Aldrich) Were mixed in equimolar amounts (100 μM each) to obtain the above mixture.

(5) Luciferase assay The olfactory receptor expressed in HEK293 cells is coupled with intracellular Gαs to activate adenylate cyclase, thereby increasing the amount of intracellular cAMP. For the measurement of odor response in this study, a luciferase reporter gene assay was used which monitors the increase in intracellular cAMP level as a luminescence value derived from the firefly luciferase gene (fluc2P-CRE-hygro). In addition, a renilla luciferase gene fused to the downstream of the CMV promoter (hRluc-CMV) was introduced at the same time, and used as an internal standard for correcting errors in gene transfer efficiency and cell number.
From the culture prepared in (3) above, the medium was removed with Pipetman, and 75 μl of a solution containing a trans-2-hexenal / cis-3-hexenol mixture (100 μM each) prepared with DMEM (Nacalai Tesque) was added. . The cells were cultured at 37 ° C. for 4 hours in a CO ₂ incubator to fully express the luciferase gene in the cells. After the plate was left at room temperature for 10 minutes, the response of each olfactory receptor was evaluated by measuring the amount of luciferase accumulated in the cells using Dual-Glo ^™ luciferase assay kit (Promega). The activity of luciferase was measured using a Dual-Glo ^™ luciferase assay system (promega) according to the operation manual of the product. A value obtained by dividing the luminescence value derived from firefly luciferase induced by the test substance stimulation by the luminescence value in the cells not subjected to the test substance stimulation was calculated as a fold increase and used as an index of the response intensity.

(6) Results Seven types of olfactory receptors OR1A1, OR2J3, OR2W1, OR5K1, OR5P3, OR10A6 and OR51I2 showed a response to the scent of a trans-2-hexenal / cis-3-hexenol mixture (FIG. 1). .
Of these, OR2J3 and OR2W1 are already known to be receptors for cis-3-hexenol, but it is not known whether they are responsive to mixtures with trans-2-hexenal. Also, the other five receptors are receptors that have not been reported to respond to the scent of a trans-2-hexenal / cis-3-hexenol mixture.

Example 2 Response of perfume mixture to OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 (1) Preparation of perfume mixture Methyl 2-naphthyl ketone (Sigma-Aldrich), l-carvone ((-)-1- Methyl-4-isopropenyl-6-cyclohexen-2-one: Wako Pure Chemical Industries), methylisoeugenol (1,2-dimethoxy-4- (1-propenyl) benzene: Sigma-Aldrich), and phenylethyl acetate (2- Four kinds of fragrance compounds (phenylethyl ester: Sigma-Aldrich) were mixed in equimolar amounts to obtain a fragrance mixture A.
(2) OR1A1, OR2J3, OR2W1, OR5K1, OR5P3, OR10A6 and OR51I2 expressed in HEK293 cells in the same procedure as in Example 1 were stimulated with the fragrance mixture A prepared in (1), and olfactory reception Body responsiveness was evaluated.

(3) Results Fragrance mixture A strongly activated the receptors of OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 (FIG. 2).

Example 3 Fatigue Suppression Effect of Fragrance Mixture (1) A 1 hour Stroop color word test was performed on 20 healthy men. Problems were displayed one after another at 1.5 second intervals, and the subjects were instructed to answer as quickly and accurately as possible. The performance evaluation was performed by analyzing the correct answer rate of the Stroop color word test. During the Stroop Color Ward test, no scent (water), trans-2-hexenal / cis-3-hexenol mixture prepared in Example 1 (4) (final concentration 0.25%), Example 2 ( The fragrance mixture A (final concentration 0.02%) prepared in 1) was filled into the room with an aroma diffuser (MUJI). The subjects were divided into the following three groups, and the test was carried out with an interval of one week between each scent.

First group: no fragrance → trans-2-hexenal / cis-3-hexenol mixture → fragrance mixture A
Group 2: Trans-2-hexenal / cis-3-hexenol mixture → fragrance mixture A → no fragrance Group 3: Fragrance mixture A → no fragrance → trans-2-hexenal / cis-3-hexenol mixture

(2) Results As a result of analyzing the correct answer rate for 30 minutes from the start of the Stroop Color Ward test with reference to the correct answer rate without fragrance, the correct answer was obtained with the scent of the trans-2-hexenal / cis-3-hexenol mixture and the scent of the fragrance mixture A. There was no significant difference in rate. From the above results, it was shown that the fragrance mixture A exhibited a fatigue suppressing effect, and the effect was equivalent to the trans-2-hexenal / cis-3-hexenol mixture (FIG. 3).

Claims (5)

The search method of the fatigue inhibitor or its candidate substance including the following process a) -c).
a) adding a test substance to an olfactory receptor polypeptide comprising OR1A1, OR2J3, OR2W1, OR5K1, OR5P3 and OR10A6 b) measuring a response of the receptor polypeptide to the test substance c) a measured response Selecting a test substance that enhances the response as a fatigue inhibitor or a candidate substance thereof based on   The olfactory receptor polypeptide is an olfactory receptor expressed on a cell that naturally expresses the olfactory receptor polypeptide or on a recombinant cell genetically engineered to express the olfactory receptor polypeptide The method of claim 1.   The method according to claim 1 or 2, further comprising a step of measuring a response of an olfactory receptor polypeptide to which no test substance is added.   If the response of the olfactory receptor to which the test substance is added is 1.1 times or more than the response of the olfactory receptor to which the test substance is not added, the test substance is used as a fatigue inhibitor or a candidate substance thereof 4. The method of claim 3, wherein   The method according to any one of claims 1 to 4, wherein the step of measuring the response of the receptor is performed by a reporter gene assay.