ACETYLCHOLINE RECEPTOR-BINDING PEPTIDE

Abstract
The present disclosure relates to an acetylcholine receptor-binding peptide and, more particularly, to novel peptides which exhibit a wrinkle amelioration effect by binding the peptides to an acetylcholine receptor on which acetylcholine acts, thereby blocking secretion of acetylcholine. Peptides according to the present disclosure suppress secretion of acetylcholine by having a high binding strength with the acetylcholine receptor, thereby strongly binding the peptides to acetylcholine. Therefore, a cosmetic composition and a pharmaceutical composition comprising the peptides according to the present disclosure as an active ingredient exhibit an excellent wrinkle ameliorating effect.
Description
BACKGROUND OF THE INVENTION
Field of the Invention

The present disclosure relates to an acetylcholine receptor-binding peptide and, more particularly, to peptides which exhibit a wrinkle amelioration effect by binding the peptides to an acetylcholine receptor on which acetylcholine acts, thereby blocking secretion of acetylcholine.


Related Art

Recently, consumers' needs for cosmetics have been gradually changed from requesting uses for decorating themselves beautifully to requesting functional uses of the cosmetics due to an increase in interest for healthy life, improvement of the standard of living, an increase in the entry of women in public affairs, the acceleration of aging, etc.


Research activities intended for developing bioactive substances having a wrinkle amelioration effect has consistently progressed to prevent skin aging phenomenon and maintain more healthy and elastic skin. Typically, tretinoin (trans-retinoic acid) as a therapeutic agent for improving photoaged skin received United States FDA permission in 1995, and wrinkle ameliorating cosmetics have been started to be marketed in earnest while retinol having less side effects than tretinoin has been used in raw materials for cosmetic products from the middle and late 1990s. Thereafter, female hormone-like substances, antioxidants extracted from various plants, etc. as wrinkle ameliorating raw materials have been introduced into cosmetics.


However, most of such raw materials for cosmetic products have been had various problems including inept efficacy, causing of skin side effects, etc. Further, the present raw materials for cosmetic products have not been able to sufficiently satisfy needs of consumers wanting newer, stronger and more fundamental amelioration of wrinkles since the present raw materials for cosmetic products have limited application ranges to the skin, and most of the present raw materials for cosmetic products are similar in efficacies on the skin such as promotion of collagen synthesis, inhibition of collagen decomposition, and removal of active oxygen although present raw materials for cosmetic products are raw materials with good efficacies. Accordingly, researches on raw materials and technologies which are capable of establishing new skin aging mechanisms, and blocking or delaying skin aging based on recent dermatological theories have been actively progressed in cosmetic industries.


Recently, a study of ameliorating skin wrinkles by using a peptide component in cosmetics has been actively proceeded. Peptides, as material formed by coupling two or more amino acids, are produced by chemical synthesis, enzyme reaction, or hydrolysis from protein.


On the other hand, acetylcholine is involved in movements of skeletal muscles and visceral muscle in the peripheral nervous system, and has an effect on learning and memory in the brain. When secretion of acetylcholine, i.e., neurotransmitter is hindered at places where a motor nerve and muscles meet, acetylcholine inhibits contraction of the muscles such that wrinkles are spread while the muscles are being paralyzed. Botox corresponds to an example using this. Botox blocks a process of secreting acetylcholine, i.e., material that is essential in contraction of the muscles at a motor nerve terminal. As a result, the muscles cannot be moved, and wrinkles caused by the muscles are removed.


Therefore, if peptides of inhibiting secretion of acetylcholine are developed by the same principle, it is predicted that amelioration and prevention of skin wrinkles can be expected.


PRIOR ART DOCUMENT
Patent Document



  • (Patent document 1) Korea Patent Registration Publication No. 10-0553174



SUMMARY OF THE INVENTION

The purpose of the present disclosure is to provide peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor.


To achieve the purpose, an acetylcholine receptor-binding peptide comprising an amino acid sequence represented by any one of the following general formulas I to 6 according to an aspect of the present disclosure is provided:





WTWKG-Xn  [General Formula 1]





TWKG-Xn  [General Formula 2]





WKG-Xn  [General Formula 3]





KG-Xn  [General Formula 4]





G-Xn  [General Formula 5]





Xn  [General Formula 6]


wherein the Xn indicates a sequence comprised of 1 to 6 any amino acids.


The term in the present disclosure, “peptides or fragments thereof”, means a polymer comprised of two or more amino acids connected by an amide bond (or peptide bond). For the purpose of the present disclosure, the peptides or the fragments thereof means peptides which exhibit a wrinkle amelioration effect or fragments thereof.


Peptides or fragments thereof of the present disclosure may include an additional amino acid sequence devised as a specific purpose for increasing stability of targeting sequence, tag, labelled residues, half-life or peptides.


Peptides or fragments thereof of the present disclosure may be obtained by various methods well known in the art. Specifically, peptides or fragments thereof of the present disclosure may be produced by using genetic recombination or protein expression system, or may be produced by a method of synthesizing the peptides or the fragment thereof in vitro through chemical synthesis such as peptide synthesis, and a cell-free protein synthesis method.


More specifically, although the peptides or the fragment thereof not only may be synthesized by a method well known in the art, e.g., an automatic peptide synthesizer, but also may be produced by genetic engineering technology, the present disclosure is not limited thereto. For example, desired peptides can be produced by cutting and separating peptides according to the present disclosure from the fusion protein by using protease or a compound after preparing a fusion gene which encodes a fusion protein formed of a fusion partner and peptides according to the present disclosure through gene manipulation, transforming the fusion gene into a host microbe, and expressing the host microbe in the form of a fusion protein. To this end, for instance, a DNA sequence encoding amino acid residues which can be cut by protease such as Factor Xa or enterokinase and a compound such as CNBr or hydroxylamine may be inserted between the fusion partner and a peptide gene of the present disclosure.


In peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor of the present disclosure, the Xn may have any one amino acid sequence among the following sequence numbers 1 to 11:











[Sequence number 1]



KGTLNR,







[Sequence number 2]



RKSLLR,







[Sequence number 3]



EDKGKN,







[Sequence number 4]



RDKLQM,







[Sequence number 5]



QLGQLS,







[Sequence number 6]



GRLSAS,







[Sequence number 7]



RQLNNQ,







[Sequence number 8]



DNLQNN,







[Sequence number 9]



LYQRLG,







[Sequence number 10]



NKQVKF,



and







[Sequence number 11]



ETYDSK






In peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor of the present disclosure, the peptides may comprise any one amino acid sequence among the following sequence numbers 12 to 22:












Sequence number 12:
WTWKGKGTLNR,







Sequence number 13:
WTWKGRKSLLR,







Sequence number 14:
WTWKGEDKGKN,







Sequence number 15:
WTWKGRDKLQM,







Sequence number 16:
WTWKGQLGQLS,







Sequence number 17:
WTWKGGRLSAS,







Sequence number 18:
WTWKGRQLNNQ,







Sequence number 19:
WTWKGDNLQNN,







Sequence number 20:
WTWKGLYQRLG,







Sequence number 21:
WTWKGNKQVKF,



and








Sequence number 22:
WTWKGETYDSK






In peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor of the present disclosure, the acetylcholine receptor-binding peptide comprises any one sequence among amino acid sequences represented by the following sequence numbers 23 to 26:












Sequence number 23:
WTWKGKGTLNR,







Sequence number 24:
WTWKGRKSLLR,







Sequence number 25:
WTWKGEDKGKN,



and








Sequence number 26:
WTWKGRDKLQM






In peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor of the present disclosure, the acetylcholine receptor-binding peptide comprises any one sequence among amino acid sequences represented by the following sequence numbers 27 to 31. The amino acid sequences represented by the following sequence numbers 27 to 31 are structures in which some of amino acid sequences represented by the sequence numbers 23 to 26 bear fruit for optimization:












Sequence number 27:
TWKGKGTLNR,







Sequence number 28:
WKGKGTLNR,







Sequence number 29:
WTWKGKGTLN,







Sequence number 30:
WTWKGKGTL,



and








Sequence number 31:
KGTLNR






A method of screening an acetylcholine receptor-binding peptide according to another aspect of the present disclosure is provided. The method comprises the steps of:


(1) preparing a recombinant phage by inserting the peptide library into a vector after preparing a peptide library;


(2) mixing the recombinant phage with an acetylcholine receptor, and biopanning a mixture of the recombinant phage and the acetylcholine receptor to select a phage which is bound to the acetylcholine receptor;


(3) performing an enzyme-linked immunosorbent assay (ELISA) of the acetylcholine receptor and a control group with respect to the phage selected in the step (2); and


(4) analyzing performance results of the ELISA to select a phage having an acetylcholine receptor-binding signal intensity of 1.5 time or more compared to the control group.


In a method of selecting peptides which suppress secretion of acetylcholine by binding the peptides to an acetylcholine receptor of the present disclosure, the peptide library in the step (1) of preparing a recombinant phage by inserting the peptide library into a vector after preparing a peptide library may be prepared by using a DNA library comprised of any one base sequence among the sequence numbers 1 to 11.


Furthermore, the present disclosure provides a polynucleotide encoding peptides according to the present disclosure. Further, as long as a polynucleotide comprising base sequences showing homology with the base sequence can encode peptides which are capable of showing a bonding activity with respect to the biostructure, the polynucleotide can be also included in a category of the polynucleotide provided in the present disclosure, wherein the polynucleotide may become a polynucleotide comprising base sequences showing preferably 80% or more of homology, more preferably 90% or more of homology, or most preferably 95% or more of homology.


Furthermore, a cosmetic composition for wrinkle amelioration comprising peptides according to the present disclosure as an active ingredient according to another aspect of the present disclosure is provided.


Furthermore, a pharmaceutical composition for wrinkle amelioration comprising the above-mentioned peptides as an active ingredient according to another aspect of the present disclosure is provided.


A pharmaceutical composition for wrinkle amelioration of the present disclosure may comprise peptides according to the present disclosure or pharmaceutically acceptable salts thereof alone, or may further comprise one or more pharmaceutically acceptable carriers, excipients or diluents thereof.


In the present disclosure, the term “pharmaceutically acceptable” means that the salts, carriers, excipients or diluents of the peptides are contained in the pharmaceutical composition in such sufficient amount extents that can exhibit a treatment effect, do not cause side effects, and may be easily determined by a person of ordinary skill in the art according to elements well-known to the medical field including types of diseases, age, weight, health and gender of a patient, sensitivity of the patient to drug, administration route, administration method, administration frequency, treatment period, mixing, a drug simultaneously used, etc.


For example, the pharmaceutically acceptable carriers may further comprise carriers for oral administration or carriers for non-oral administration.


The carriers for oral administration may include lactose, starch, cellulose derivatives, magnesium, stearate, stearic acid, etc. Further, the carriers for non-oral administration may include water, suitable oil, a saline solution, water-based glucose, glycol, etc., and may additionally include a stabilizer and a preservative. A suitable stabilizer may include an antioxidant such as sodium bisulfite, sodium sulfite or ascorbic acid. A suitable preservative may include benzalkonium chloride, methyl- or propyl-paraben, or chlorobutanol. Carriers described in the following document may be referred to as other pharmaceutically acceptable carriers (Remington's Pharmaceutical Sciences, 19th ed., Mack Publishing Company, Easton, Pa., 1995).


A pharmaceutical composition for wrinkle amelioration of the present disclosure can be administered to mammals including human by any method. For example, a pharmaceutical composition for wrinkle amelioration of the present disclosure can be administered by oral administration or non-oral administration. Although the present disclosure is not limited thereto, the non-oral administration may be intravenous administration, intramuscular medication, intraarterial administration, intramedullary administration, intrathecal administration, intraperitoneal administration, dermal administration, subcutaneous administration, intraperitoneal administration, intranasal administration, intestinal administration, topical administration, sublingual administration, or intrarectal administration. Preferably, a pharmaceutical composition according to the present disclosure can be dermally administered. The ‘dermal administration’ in the above description indicates that an active ingredient contained in the composition according to the present disclosure is enabled to be transferred into the skin by administering a pharmaceutical composition according to the present disclosure into cells or skin. For example, a pharmaceutical composition according to the present disclosure is prepared into an injection type formulation such that a pharmaceutical composition according to the present disclosure may be administered by a method of lightly pricking the injection type formulation into the skin with a 30-gauge thin injection needle or a method of directly applying the injection type formulation to the skin.


A pharmaceutical composition according to the present disclosure may be formulated into a preparation for oral administration or a preparation for non-oral administration along the above-described administration routes.


In case of the preparation for oral administration, the composition according to the present disclosure can be formulated into powder, granule, tablet, pill, sugar-coated table, capsule, liquid, gel, syrup, slurry, suspension, etc. by methods known in the art. For example, the preparation for oral administration may include tablet or sugar-coated tablet which are obtained by mixing an active ingredient with a solid excipient, pulverizing a mixture of the active ingredient and the solid excipient, adding a suitable supplemental agent to a pulverized material, and processing a supplemental agent-added pulverized material into a granule mixture. Examples of a suitable excipient may comprise saccharides including lactose, dextrose, sucrose, sorbitol, mannitol, xylitol, erythritol, maltitol, etc., starches including corn starch, wheat starch, rice starch, potato starch, etc., celluloses including cellulose, methyl cellulose, sodium carboxymethyl cellulose, hydroxypropyl methylcellulose, etc., and fillers including gelatin, polyvinylpyrrolidone, etc. Further, in some cases, crosslinked polyvinylpyrrolidone, agar, alginic acid, sodium alginate, or the like may be added as a disintegrating agent.


The preparation for non-oral administration can be formulated in the form of injection, cream, lotion, ointment for external application, oil, moisturizer, gel, aerosol, and nasal inhaler by methods known in the art. All of these formulations are described in a document, i.e., a prescription generally known in the pharmaceutical field (Remington's Pharmaceutical Science, 15th Edition, 1975, Mack Publishing Company, Easton, Pa. 18042, Chapter 87: Blaug, Seymour).


Total therapeutically effective amount of peptides according to the present disclosure may be administered to patients with single dose or multiple dose of fractionated treatment protocol. An active ingredient included in a pharmaceutical composition according to the present disclosure may vary according to the severity of a disease.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is results of preparing random peptide DNA libraries according to an embodiment of the present disclosure.



FIG. 2 is results of checking if specificity for an acetylcholine receptor has been increased in a biopanning step according to an embodiment of the present disclosure.



FIG. 3 illustrates ELISA results for the acetylcholine receptor compared to streptavidin, i.e., a negative control group of a recombinant phage recovered in the biopanning step according to an embodiment of the present disclosure.



FIG. 4 is multiple alignment results of peptides selected by sequencing of a recombinant phage having 1.5 time or more of a signal ratio of the acetylcholine receptor to streptavidin in the ELISA results according to an embodiment of the present disclosure.



FIG. 5 is results of measuring binding ability values of the selected peptides and Synake and Vialox which are a positive control group according to an embodiment of the present disclosure.



FIG. 6 is results of measuring binding ability values of Synake which is a positive control group according to an embodiment of the present disclosure.



FIG. 7 is results of measuring binding ability values of the selected peptides according to an embodiment of the present disclosure.



FIG. 8 is results of comparing binding ability values of deleted peptides for optimization according to an embodiment of the present disclosure.



FIG. 9 is results of measuring binding ability values of the deleted peptides according to an embodiment of the present disclosure.



FIG. 10 is results of measuring affinity values of the deleted peptides according to an embodiment of the present disclosure.





DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, the present disclosure will be described in more detail through Examples. It will be obvious to a person having ordinary skill in the art that these examples are illustrative purposes only and are not to be construed to limit the scope of the present disclosure.


Example 1. Preparing Random Peptide Phage Libraries

1-1. Preparing 4 Mer, 5 Mer and 6 Mer Random Peptides and Inserting the Prepared Random Peptides into Vector


In order to prepare random peptide libraries (WTWKG(X)n, X=random amino acids, n=4 to 6), DNA libraries 4mer (TTCTATGCGGCCCAGCTGGCCTGGACATGGAAGGGANNKNNKNNKNNKGCGGC CGCAGAAACTGT), 5mer (ITCTATGCGGCCCAGCTGGCCTGGACATGGAAGGGANNKNNKNNKNKKNNKGC GGCCGCAGAAACTGTT), and 6mer (TTCTATGCGGCCCAGCTGGCCTGGACATGGAAGGGANNKNNKNNKNNKNKKNN KGCGGCCGCAGAAACTGTT) were synthesized (Bioneer, Daejeon, Korea).


Double strand insert was amplified by using PCR as two single strand primers (TTCTATGCGGCCCAG and AACAGTTTCTGCGGC). Preparation results of random peptide DNA libraries are illustrated in FIG. 1.


In order to insert the random peptide DNA libraries into a phagemid vector (pIGT), insert DNA amplified using the phagemid vector and PCR was treated with restriction enzymes.


After reacting about 10 μg of the insert DNA with SfiI (New England Biolab (NEB)), Ipswich) and NotI (NEB, Ipswich) for 8 hours, a purified DNA was obtained by using a PCR purification kit. Further, after treating about 10 μg of the phagemid vector with SfiI and NotI for 8 hours and injecting CIAP (Calf Intestinal Alkaline Phosphate) (NEB, Ipswich) into the phagemid vector treated with SfiI and NotI to react CIAP with the phagemid vector treated with SfiI and NotI, a reaction product was purified by using the PCR purification kit. Purification results are illustrated in FIG. 1, and 1.8×109 of 4 mer peptide library DNAs, 3.2×108 of 5 mer peptide library DNAs and 5.9×108 of 6 mer peptide library DNAs were respectively prepared.


After connecting an insert DNA (3 μg) to a phagemid vector (10 μg) at 18° C. for 15 hours by using a T4 DNA ligase (Bioneer, Daejeon, Korea), the DNAs were dissolved in 100 μl of a TE buffer by precipitating the phagemid vector connected to the T4 DNA ligase with ethanol.


1.2 Electroporation


After dividing 100 μl of a phagemid vector including the respective 4 mer, 5 mer and 6 mer random insert DNAs that had been prepared in the Example 1.1 into 25 phagemid vectors each having 4 μl, an electroporation process was performed on the 25 phagemid vectors each having 4 μl.


More specifically, after melting a competent cell on ice, mixing 200 μl of the competent cell with each of 4 μl of phagemid vector solutions including the insert DNAs, and injecting the mixed solutions into a 0.2 cm cuvette that had been cooled and prepared, the resulting materials were put on ice for 1 minute.


After programming an electroporator (BioRAD, Hercules, Calif.) under conditions of 25 ρF and 2.5 kV at 25Ω, removing water of the prepared cuvette, and positioning the cuvette in the electric perforator, a pulse was applied to the electroporator (time costant was 4.5 to 5 msec). Then, after immediately inserting the electroporated materials into a LB (Luria Bertani) liquid culture medium including 20 mM of glucose that had been prepared at 37° C. to obtain cells with the total amount of 25 ml, the obtained cells with the total amount of 25 ml were moved to 100 ml test tubes. After culturing the cells while mixing the cells by a speed of 200 rpm at 37° C. for one hour, dividing the cultured cells into 10 μl of the cultured cells, and diluting 10 μl of the divided cultured cells, 10 μl of the diluted cultured cells was spread on an ampicillin agar medium to measure the number of libraries. After injecting cells remained after performing the dividing process along with 20 mM of glucose and 50 μg/ml of ampicillin into 1 L of LB, the cells were cultured at 30° C. for one day. After centrifuging the culture solution to a speed of 4,000 rpm at 4° C. for 20 minutes to remove a supernatant except settled cells from the centrifuged culture solution, re-suspending the supernatant-removed centrifuged culture solution with 40 ml of LB, and injecting glycerol with a final concentration of 20% or more into the re-suspension, the glycerol-injected re-suspension was stored at −80° C.


1.3 Producing Recombinant Phages from Random Peptide Libraries


Recombinant phages were produced from 4 mer, 5 mer and 6 mer random peptide libraries stored at −80° C. in Example 1.2.


After adding 1 ml of the libraries that had been stored at −80° C. to 30 ml of an SB liquid culture medium, a culturing process was performed to obtain culture solutions by mixing the libraries with the SB liquid culture medium to a speed of 200 rpm at 37° C. for 20 minutes. After injecting a helper phage (1010 pfu) and ampicillin (final concentration of 50 μg/ml) into the culture solutions, and a culturing process was performed again under the same conditions for 1 hour. Recombinant phages were produced by moving the culture solutions to 30 ml of an SB liquid culture medium including ampicillin (50 μg/ml) and kanamycin (10 μg/ml) and culturing mixed solutioned of the culture solutions and the SB liquid culture medium under the same conditions for 16 hours or more. After centrifuging the produced recombinant phages to a speed of 5,000 rpm at 4° C. for 10 minutes to obtain supernatants, mixing PEG/NaCl with the supernatants at a volume ratio (v/v) of 5:1, leaving along the mixed solutions on ice for 1 hour, and centrifuging the mixed solutions to a speed of 13,000 rpm at 4° C. for 20 minutes to carefully remove the supernatants, pellets were resuspended in the supernatant-removed centrifuged solutions with 1 ml of PBS (phosphate buffered saline).


Example 2. Method of Screening Peptides to be Linked to an Acetylcholine Receptor

2.1 Biopanning of Acetylcholine Receptor


After putting acetylcholine receptor (AchR) alpha 1 (10 μg/ml) into 8 wells of 96 well high binding plates in an amount as much as 50 μl, leaving alone the acetylcholine receptor (AchR) alpha 1 put into the 8 wells at 4° C. overnight, washing the acetylcholine receptor (AchR) alpha 1 put into the 8 wells with 200 μl of PBS once the next day, putting 200 μl of 2% BSA (Bovine Serum Albumin) into the acetylcholine receptor (AchR) alpha 1 washed with PBS to obtain a mixture, blocking the mixture at room temperature for 2 hours, and removing all solution from the mixture, a resulting material was washed with 200 μl of PBS three times.


After mixing the washed resulting material with 400 μl of a solution including the 4 mer, 5 mer and 6 mer random peptide recombinant phages each prepared in Example 1.3 and 400 μl of 2% BSA to obtain a mixture, putting the mixture into 8 wells in an amount of 100 μl per well, the mixture put into the wells was left alone at room temperature for 1 hour, removing all solution from the mixture in the 8 wells, washing the solution-removed mixture with 0.1% PBST (tween-20) three times, putting 0.2 M glycine (pH 2.2) into the washed mixture in an amount of 100 μl per well to elute the phages for 10 minutes, and collecting the eluted phages in 800 μl of an E-tube, 200 μl of 1 M Tris (pH 9.0) was put into the eluted phages collected in the E-tube to obtain a neutralized material.


In order to measure the number of input phages and the number of output phages per each of biopannings, after mixing the neutralized material with E. coli with OD=0.7, the mixture was spread on an agar culture medium including ampicillin. In order to repeatedly perform a panning process, after mixing 500 μl of the output phages with 5 ml of E. coli to a rotation speed of 200 rpm at 4° C. for 30 minutes, and culturing the output phages mixed with E. coli to obtain a culture medium, a culturing process was performed in the same manner for 30 minutes by adding ampicillin (50 μg/ml) and helper phage (lx 1010 pfu) to the culture medium. Then, after moving a culture solution to 50 ml of an SB culture medium including ampicillin (50 μg/ml) and kanamycin (10 μg/ml), the culturing process was performed in the same manner for 1 day to obtain a culture solution. After centrifuging the culture solution to a speed of 5,000 rpm at 4° C. for 10 minutes and adding PEG/NaCl [20% PEG(w/v) and 15% NaCl(w/v)] to a supernatant of the centrifuged culture solution at a ratio of 5:1, the mixed solution was settled on ice for 1 hour. After centrifuging the settled solution to a speed of 13,000 rpm at 4° C. for 20 minutes, completely removing a supernatant from the centrifuged solution, and suspending phage pellets with 1 ml of a PBS solution to obtain a suspension, the suspension was used in a second biopanning process. The same method was used in each panning step as described above, the washing processes were performed 3 times, 5 times, 7 times and 10 times respectively, and conditions at which the process of biopanning 6 mer libraries (S6) was performed over 5 times with respect to an acetylcholine receptor protein and results of the input phages and the output phages are shown in the following Table 1.









TABLE 1







S6 Biopanning











Conditions
Name
Input
Output
Output/Input





AchR 10 μg/ml
1st S6
28 * 400 * 106 = 1.12 * 1010
21 * 1000 * 102 = 2.1 * 106
18.75 * 10−5


Binding 30° C.


Incubation 1 h


PBST 0.1%


Washing 3 times


AchR 10 μg/ml
2nd S6
9 * 400 * 106 = 3.6 * 109
4 * 1000 * 102 = 4 * 105
11.1 * 10−5


Binding 30+ C.


Incubation 1 h


PBST 0.1%


Washing 5 times


AchR 10 μg/ml
3rd S6
128 * 400 * 106 = 5.12 * 1010
20 * 1000 * 102 = 2.0 * 106
 3.9 * 10−5


Binding 30° C.


Incubation 1 h


PBST 0.1%


Washing 7 times


AchR 10 μg/ml
4th S6
79 * 400 * 106 = 3.16 * 1010
75 * 1000 * 102 = 7.5 * 106
23.7 * 10−5


Binding 30° C.


Incubation 1 h


PBST 0.1%


Washing 10 times


AchR 10 μg/ml
5th S6
104 * 400 * 106 = 4.16 * 1010
82 * 1000 * 102 =8.2 * 106
19.7 * 10−5


Binding 30° C.


Incubation 1 h


PBST 0.1%


Washing 10 times









2.2 ELISA of Input Phages of Acetylcholine Receptor (AchR)


ELISA of respective input phages of the above-mentioned libraries was performed on streptavidin and acetylcholine receptor (AchR).


After putting 10 μg/ml of the acetylcholine receptor into 96 well ELISA plates and putting streptavidins into 10 wells in an amount of 50 μl per well, the acetylcholine receptor put into the 96 well ELISA plates and streptavidins put into the 10 wells were left alone at 4° C. for 1 day. Then, after washing all wells with 0.05% PBST three times, blocking the washed wells at room temperature for 2 hours by using 2% BSA diluted by PBS, and removing all of solution from a blocked material, the solution-removed material was washed with 0.05% PBST three times.


After mixing 800 μl of third (3rd S6), fourth (4th S6) and fifth (5th S6) input phages, i.e., recombinant phages in Table 1 with 200 μl of 10% BSA to obtain mixtures and dividing 3 wells of the mixtures into acetylcholine receptor and streptavidin well in an amount of 100 μl, the resulting materials were settled at 30° C. for 1 hour. After washing the settled materials with a 0.05% PBST solution three times and diluting HRP-conjugate anti-M13 antibody (GE Healthcare) to 1:1,000 to obtain a diluted solution, and the washed materials were reacted with the diluted solution at 30° C. for 1 hour. After washing reaction products with 0.05% PBST three times and dividing 100 μl of a solution of tetramethylbenzidine (TMB) (BD Science), i.e., a substrate of peroxidase into the washed reaction products to induce a chromogenic reaction, the reaction was stopped by adding 100 μl of 1M HCl to the chromogenic reaction-induced materials. Thereafter, absorbance values of the resulting materials were measured at 450 nm. Results of measuring the absorbance values are illustrated in FIG. 2.


2.3 Specific Phage Searching in Acetylcholine Receptor (Colony ELISA)


After inoculating fourth (4th S6) and fifth (5th S6) output phages in Table 1 into E. coli, the fourth (4th S6) and fifth (5th S6) output phages inoculated into E. coli were spread to obtain about 100 to 200 plaques per plate. After inoculating 50 plaques into 1 ml of an SB-ampicillin (50 μg/ml) culture solution using a sterilized tip, performing a process of shake-culturing the plaque-inoculated culture solutions at 37° C. for 5 hours, and adding 30 μl of a helper phage to the shake-cultured solutions, the mixed solutions were cultured to a speed of 200 rpm at 37° C. for 1 day to obtain culture solutions. After centrifuging the culture solutions to a speed of 12,000 rpm for 2 minutes to recover supernatants from the centrifuged culture solutions, and putting 2% BSA into the recovered supernatants, the supernatants having the 2% BSA put thereinto were used for searching the phages.


After putting 5 μg/ml of the acetylcholine receptor into the 96 well ELISA plates and putting streptavidins into 50 wells in an amount of 50 μl per well, the acetylcholine receptor put into the 96 well ELISA plates and streptavidins put into the 50 wells were left alone at 4° C. for 1 day. On the next day, after removing proteins of all wells, blocking the removed proteins at room temperature for 2 hours by using 2% BSA, and throwing away solutions from the blocked proteins, resulting materials were washed with 0.05% PBST. After dividing phage solutions amplified per each of clones into all wells in an amount of 100 μl, the divided phage solutions were settled at 30° C. for 1 hour. After washing the settled materials with a 0.05% PBST solution three times, diluting HRP-conjugate anti-M13 antibody (GE Healthcare) to 1:2,000 to obtain a diluted solution, and dividing the washed materials into the diluted solution in an amount of 100 μl, the washed materials were reacted with the diluted solution at 30° C. for 1 hour. After washing reaction products with 0.05% PBST three times and dividing 100 μl of the TMB solution into the washed reaction products to induce a chromogenic reaction, the reaction was stopped by adding 100 μl of 1M H2SO4 to the chromogenic reaction-induced materials. Thereafter, results are illustrated in FIG. 3.


Referring to FIG. 3, sequencing was requested by purifying plasmids of phages having 1.5 time or more of an acetylcholine receptor signal compared to streptavidin (Bioneer, Deajon, Korea). GATTACGCCAAGCTITGGAGC was used as a sequencing primer.


Peptide sequences having specific binding abilities in the acetylcholine receptor through sequencing are shown FIG. 4 and the following Table 2.









TABLE 2







Peptide sequences













Duplication



Name
Sequences
number







S6_1
WTWKGKGTLNR
6/16







S6_2
WTWKGRKSLLR
1/16







S6_3
WTWKGEDKGKN
1/16







S6_4
WTWKGRDKLQM
1/16







S6_5
WTWKGQLGQLS
1/16







S6_6
WTWKGGRLSAS
1/16







S6_7
WTWKGRQLNNQ
1/16







S6_8
WTWKGDNLQNN
1/16







S6_9
WTWKGLYQRLG
1/16







S6_10
WTWKGNKQVKF
1/16







S6_11
WTWKGETYDSK
1/16










Example 3. Experiment of Comparing Acetylcholine Binding Forces of Discovered Peptides

S6_1 (WTWKGKGTLNR), S6_2 (WTWKGRKSLLR), S6_3 (WTWKGEDKGKN), S6_4 (WTWKGRDKLQM) showing sequence similarities through multiple alignments among the peptides in Table 2 were synthesized.


A surface plasmon resonance (SPR) experiment was progressed using a biosensor chip to compare binding forces for the acetylcholine receptors thereof (Biacore 3000, Biacore AB, Uppsala, Sweden). After fixing selected acetylcholine receptor proteins to a CM5 chip (Biacore) using EDC/NHS, association and dissociation were observed for up to 500 seconds. A binding force comparing experiment was carried out under observation conditions of a running buffer of 20 mM Tris (pH 7.4), a speed of 30 μl/min, and a peptide concentration of 10 μM (S6_1, S6_2, S6_3, S6_4). Results of the binding force comparing experiment are shown in FIG. 5.


Example 4. Experiment of Comparing Binding Forces of Discovered Peptides S6_1 and a Positive Control Group

A surface plasmon resonance (SPR) experiment was progressed using a biosensor chip to compare binding forces for acetylcholine receptors of S6_1(WTWKGKGTLNR), i.e., discovered peptides and Sc_1_C6(KGTLNR), i.e., a deleted form, and Synake and Vialox, i.e., a positive control group (Biacore 3000, Biacore AB, Uppsala, Sweden).


After fixing selected acetylcholine receptor proteins to a CM5 chip (Biacore) using EDC/NHS, association and dissociation were observed for up to 500 seconds. A binding force comparing experiment was carried out under observation conditions of a running buffer of 20 mM Tris (pH 7.4), a speed of 30 μl/min, and a peptide concentration of 10 μM (Synake, Vialox, S6_1, S6_1_C6). Results of the binding force comparing experiment are shown in FIG. 6.


Example 5. Measuring Affinity Values of S6_1 Peptides and Synake Peptides

A surface plasmon resonance (SPR) experiment was progressed using a biosensor chip to check affinity values for acetylcholine receptors of S6_1(WTWKGKGTLNR), i.e., discovered peptides and Synake, i.e., a positive control group (Biacore 3000, Biacore AB, Uppsala, Sweden). After fixing the acetylcholine receptors to a CM5 chip (Biacore) using EDC/NHS, association and dissociation were observed for up to 500 seconds. A binding ability comparing experiment was carried out under observation conditions of a running buffer of 20 mM Tris (pH 7.4), a speed of 30 μl/min, a concentration of 10 to 50 μM (Synake), and a concentration of 0.1 to 10 μM (peptides S6_1). Respective results of the binding ability comparing experiment are shown in FIG. 7 (Synake) and FIG. 8 (peptides S6_1).


Example 6. Experiment of Comparing Optimizations and Binding Forces of Peptides of S6_1

S6_1_C10 (TWKGKGTLNR), S6_1_C9 (WKGKGTLNR), S6_1_C10_end (WTWKGKGTLN), and S6_1_C9_end (WTWKGKGTL), i.e., peptides which each have one amino acid and two amino acids respectively removed from N-terminal and C-terminal thereof were synthesized to optimize S6_1.


A surface plasmon resonance (SPR) experiment was progressed using a biosensor chip to compare binding forces for acetylcholine receptors of these peptides (Biacore 3000, Biacore AB, Uppsala, Sweden).


After fixing selected acetylcholine receptor proteins to a CM5 chip (Biacore) using EDC/NHS, association and dissociation were observed for up to 500 seconds. An experiment of comparing optimizations and binding forces of the peptides was carried out under observation conditions of a running buffer of 20 mM Tris (pH 7.4), a speed of 30 μl/min, and a peptide concentration of 10 μM (Synake, Vialox, S6_1, S6_1_C10, S6_1_C9, S6_1_C10_end, S6_1_C9_end, and S6_1_C6). Experiment results of comparing the optimizations and binding forces of the peptides are shown in FIG. 9.


Example 7. Measuring Affinity Values of S6_1_C9 Peptides

A surface plasmon resonance (SPR) experiment was progressed using a biosensor chip to check affinity values for acetylcholine receptors of optimized S6_1_C9 peptides (WKGKGTLNR) prepared in Example 6 (Biacore 3000, Biacore AB, Uppsala, Sweden). After fixing selected acetylcholine receptor proteins to a CM5 chip (Biacore) using EDC/NHS, association and dissociation were observed for up to 500 seconds. An experiment of measuring affinity values of the peptides was carried out under observation conditions of a running buffer of 20 mM Tris (pH 7.4), a speed of 30 JP/min, and a concentration of 0.1 to 0.5 μM (peptides S6_1_C9).


Experiment results of measuring the affinity values of the peptides are shown in FIG. 10. Referring to FIG. 10, it can be confirmed that the S6_1_C9 peptides (WKGKGTLNR) exhibit about 100 times higher binding abilities than Synake for acetylcholine.


Peptides according to the present disclosure suppress secretion of acetylcholine by having a high binding strength with an acetylcholine receptor, thereby strongly binding the peptides to acetylcholine. Therefore, a cosmetic composition and a pharmaceutical composition comprising peptides according to the present disclosure as an active ingredient exhibit an excellent wrinkle ameliorating effect.


Although the present disclosure has been described along with the accompanying drawings, this is only one of various examples including the gist of the present disclosure and has an object of enabling a person having ordinary skill in the art to easily practice the invention. Accordingly, it is evident that the present disclosure is not limited to the aforementioned examples. Accordingly, the range of protection of the present disclosure should be interpreted based on the following claims, and all of technological spirits within the equivalents of the present disclosure may fall within the range of right of the present disclosure by changes, substitutions and replacements without departing from the gist of the present disclosure. Furthermore, it is evident that the configurations of some drawings have been provided to more clearly describe configurations and have been more exaggerated or reduced than actual configurations.

Claims
  • 1. An acetylcholine receptor-binding peptide comprising an amino acid sequence represented by any one or more of the following general formulas 1 to 6: WTWKG-Xn;  [General Formula 1]TWKG-Xn;  [General Formula 2]WKG-Xn;  [General Formula 3]KG-Xn;  [General Formula 4]G-Xn; and  [General Formula 5]Xn  [General Formula 6]wherein the Xn indicates a sequence comprised of 1 to 6 any amino acids.
  • 2. The acetylcholine receptor-binding peptide of claim 1, wherein the Xn is any one selected from the group consisting of the following sequence numbers 1 to 11:
  • 3. The acetylcholine receptor-binding peptide of claim 1, wherein the peptides comprise any one amino acid sequence among the following sequence numbers 12 to 22:
  • 4. The acetylcholine receptor-binding peptide of claim 1, wherein the acetylcholine receptor-binding peptide comprises any one sequence among amino acid sequences represented by the following sequence numbers 23 to 26:
  • 5. The acetylcholine receptor-binding peptide of claim 1, wherein the acetylcholine receptor-binding peptide comprises any one sequence among amino acid sequences represented by the following sequence numbers 27 to 31:
  • 6. A polynucleotide encoding the peptide of claim 1.
  • 7. A cosmetic composition for wrinkle amelioration comprising the peptide of claim 1 as an active ingredient.
  • 8. A pharmaceutical composition for wrinkle amelioration comprising the peptide of claim 1 as an active ingredient.
  • 9. A method of screening an acetylcholine receptor-binding peptide, the method comprising the steps of: (1) preparing a recombinant phage by inserting the peptide library into a vector after preparing a peptide library;(2) mixing the recombinant phage with an acetylcholine receptor, and biopanning a mixture of the recombinant phage and the acetylcholine receptor to select a phage which is bound to the acetylcholine receptor;(3) performing an enzyme-linked immunosorbent assay (ELISA) of the acetylcholine receptor and a control group with respect to the phage selected in the step (2); and(4) analyzing performance results of the ELISA to select a phage having an acetylcholine receptor-binding signal intensity of 1.5 time or more compared to the control group.
Priority Claims (1)
Number Date Country Kind
10-2017-0082039 Jun 2017 KR national
PCT Information
Filing Document Filing Date Country Kind
PCT/KR2018/007170 6/25/2018 WO 00