JP4803976B2 - Molecular sensor for intracellular IP3 measurement - Google Patents

Description

The present invention measures the concentration of inositol 1,4,5 triphosphate (hereinafter also referred to as “IP ₃ ”), which is one of the most important intracellular messengers that induce intracellular calcium signals, with high accuracy. The present invention relates to a molecular sensor that performs measurement of IP ₃ using the molecular sensor.

IP ₃ is an intracellular messenger that is produced intracellularly and induces a Ca ²⁺ signal when the cell is stimulated by neurotransmitters, hormones, growth factors, and the like. The IP ₃ receptor, which is a target to which IP ₃ specifically acts, is a Ca ²⁺ channel distributed in intracellular Ca ²⁺ storage sites (Ca ²⁺ stores) such as the endoplasmic reticulum. When the IP ₃ receptor is activated, Ca ²⁺ is released from the store into the cytoplasm.
The IP ₃ -Ca ²⁺ system plays an important role in the regulation of blood pressure, learning, immune function, endocrine and exocrine functions, inflammation, etc., and the disorder of the IP ₃ -Ca ²⁺ system is memory / learning function, motor function It has been clarified that serious damage is caused to the occurrence (Non-patent Document 1, etc.). Therefore, quantification of IP ₃ concentration is extremely important in elucidating such pathological conditions, establishing treatments and diagnostic methods, and developing drugs.
In particular, in recent years, a technique for visualizing the Ca ²⁺ reaction of living cells in real time using a Ca ²⁺ sensitive fluorescent dye such as fura-2 has been established (Non-patent Document 2). These studies have revealed that IP ₃ generates a variety of Ca ²⁺ signals with different temporal and spatial patterns. However, in the prior art can not measure the IP ₃ in the cell.

The IP ₃ quantification method currently generally used is a competitive assay using an IP ₃ binding protein, or a separation quantification of IP ₃ using an ion exchange resin (Non-patent Document 3, etc.). Since these use a radioisotope as a detection tracer, the operation is complicated. Since these methods measure the IP ₃ concentration using a sample extracted from a cell population, it was impossible to know the intracellular IP ₃ concentration and its kinetics.
In recent years, a method for quantifying the IP ₃ concentration based on a change in fluorescence intensity of a fluorescently labeled IP ₃ binding protein has been developed (Non-patent Document 4). This method is simpler than the method using a radioisotope, but is the same in that a sample extracted from a cell population is used.
Is what is most remarkable in the conventional method, localization of IP ₃ binding protein fusion gene with GFP (PH domain of PLCD) introduced into the cell, the fusion protein encoded by the gene (GFP-PHD) This is a method for analyzing changes in intracellular IP ₃ concentration (Non-patent Documents 5 and 6, Patent Document 1). This method makes it possible for the first time to know the dynamics of IP _{3 in} living cells. However, quantitative measurement is extremely difficult because it is necessary to detect minute changes in the distribution of GFP-PHD released from the cell membrane. Moreover, a confocal laser microscope is indispensable for this analysis, and its versatility is low.
Incidentally, it is known that there is a region showing IP ₃ and high affinity in IP ₃ receptor (Non-Patent Document 7, Patent Document 2).
Recently, the development of molecular probes using fluorescence resonance energy transfer (FRET) between two types of fluorescent substances (for example, fluorosaint and rhodamine, ECFP and EYFP) has attracted attention (Non-Patent Documents 8 to 10). And used for detection of various target substances and inhibitors (Patent Documents 3 and 4)

JP2000-135095 JP2000-60565 Special table 2003-513271 WO 98/40477 Matsumoto et al. Nature 379: 168-171 (1996) G.Brooker et al., Proc.Natl.Acad.Sci.USA., 87: 2813-2817 (1990) D.S.Bredt et al., Biochimi. Biophysi. Res.Commun., 159: 976-982 (1989) Mori T. et al., J. Am. Chem. Soc., 124: 1138-1139 (2002) K. Hirose, et al., Science 284: 1527-1530 (1999) T. Uchiyama et al., J. Biol. Chem., 277: 8106-8113 (2002) Japanese Pharmacopoeia (Folia Pharmacol. Jpn.) 121, 241-253 (2003) B.A.Pollok and R. Heim.Trends in Cell Bioloby, 9: 57-60 (1999) Adams SR. Et al. Nature 349: 694-697 (1991) Miyawaki A. et al., Nature 388: 882-887 (1996)

An object of the present invention is to provide a means for measuring the concentration of IP ₃ , which is one of important intracellular messengers that induce intracellular calcium signals, with high accuracy.
The method of the present invention has the following features and can solve the problems in conventional IP ₃ measurement.
(1) Since the measurement can be performed by changing the ratio of fluorescence intensities, an accurate change in intracellular IP ₃ concentration can be visualized in real time.
(2) IP ₃ can be easily quantified using a fluorometer.
(3) IP ₃ has a higher specificity for using the ligand binding site of the target at which IP ₃ receptors when causing Ca ²⁺ release reaction.
(4) It becomes possible to search for new ligands and new inhibitors of the IP ₃ receptor, and screen for new drugs having such functions.

In order to solve such a problem, the present inventors designed a molecular sensor composed of a peptide fragment containing a ligand binding site of rat IP ₃ receptor and two kinds of fluorescent substances (ECFP and EYFP). When a gene encoding this molecular sensor is introduced into a cell (SH-SY5Y cell) and IP ₃ is bound to the molecular sensor expressed in this cell, the efficiency of fluorescence resonance energy transfer between ECFP and EYFP changes, We found that the ratio of fluorescence intensities changed. In particular, when a localization signal such as a cell membrane translocation signal is further attached to this molecular sensor, the expressed molecular sensor is localized at a specific site such as the cell membrane, so that observation becomes easy.
In addition, when SH-SY5Y cells expressing a molecular sensor were stimulated with a muscarinic receptor agonist (eg, acetylcholine or carborcol), it was confirmed that the ratio of fluorescence intensity changes with increasing intracellular IP ₃ concentration. It was.

The molecular sensor of the present invention is characterized in that FRET is changed by using the ligand binding part (about 600 amino acids) rather than the entire IP ₃ receptor (about 2.7 K amino acids). Sensors of the present configuration, when the IP ₃ does not bind to the ligand binding portion of the IP ₃ receptor, whereas the ECFP and EYFP is happening close to FRET, ligand binding of IP ₃ receptors When IP ₃ binds to the moiety, the structure of this ligand binding moiety changes, presumably because ECFP and EYFP are separated and FRET does not occur. This application is based on the fact that in this way the ligand binding portion of the IP ₃ receptor IP ₃ structural changes upon binding, this simply alone is such a structure change with the entire IP ₃ receptor (FRET It seems that no structural changes that affect As a result of configuring the molecular sensor in this way, it became possible to quantify the concentration of IP ₃ that was not possible before.

That is, the present invention provides a molecular sensor comprising a ligand binding part of an IP ₃ receptor and two kinds of fluorescent substances that cause fluorescence resonance energy transfer (FRET), wherein the ligand binding part of the IP ₃ receptor has the following structure: A molecular sensor comprising the polypeptide of either (1) or (2).
(1) A polypeptide comprising the amino acid sequence from any of the amino acid sequence 265 to 489 to any one of the 842 to 868 of the amino acid sequence represented by SEQ ID NO: 1 (2) In the polypeptide of (1), 1 or a number A polypeptide having an amino acid sequence in which a single amino acid is substituted and having affinity for inositol 1,4,5 triphosphate. As the fluorescent substance, a fluorescent protein is preferable.
As the two types of fluorescent proteins, ECFP or a variant thereof and EYFP or a variant thereof are preferable. The molecular sensor may further have a localization signal.
In this molecular sensor, it is more preferable that the fluorescent protein ECFP is composed of the polypeptide (3) or (4), and the fluorescent protein EYFP is composed of the polypeptide (5) or (6). .
(3) Polypeptide (4) consisting of amino acid sequences 21 to 259 of the amino acid sequence represented by SEQ ID NO: 1 (4) In the polypeptide of (3), one or several amino acids have been deleted, substituted or added A polypeptide comprising an amino acid sequence and emitting light having a peak at 465 to 495 nm (5) Polypeptide of a polypeptide (6) (5) comprising an amino acid sequence from 899 to 1137 of the amino acid sequence represented by SEQ ID NO: 1 A polypeptide comprising an amino acid sequence in which one or several amino acids are deleted, substituted, or added, and emitting light having a peak at 522 to 548 nm.

The present invention is a DNA encoding any of the above molecular sensors.
Furthermore, the present invention is a recombinant vector containing this DNA.
Furthermore, the present invention is a transformant transformed with this recombinant vector.
Furthermore, the present invention is a cell having any one of the above molecular sensors in the cell.
Furthermore, the present invention is an animal or plant having any one of the above molecular sensors in the body.
Furthermore, the present invention irradiates the transformant, the cell or the animal or plant with light of 350 to 500 nm, measures fluorescence at 400 to 515 nm and 515 to 600 nm, and uses these fluorescence intensities as indices. This is a method for estimating the concentration (or amount) of inositol 1,4,5 triphosphate in the transformant or the cell.
Furthermore, the present invention introduces an unknown drug into the transformant, the cell, or the animal or plant, and irradiates the light with 350 to 500 nm to measure fluorescence at 400 to 515 nm and 515 to 600 nm. In this method, the ligand or inhibitor of the IP ₃ receptor is screened using the fluorescence intensity as an index.

The present invention is an IP ₃ detector comprising any one of the molecular sensors described above. In this apparatus, the molecular sensor may be placed in a solution or fixed to a substrate such as a bead, fiber, or dish.
Further, the present invention makes this apparatus and a test object contact, irradiates light of 350 to 500 nm, measures fluorescence at 400 to 515 nm and 515 to 600 nm, and uses these fluorescence intensities as an index. In this method, the concentration of inositol 1,4,5 triphosphate is estimated.
The method for bringing the device into contact with the test object depends on the configuration of the device. For example, a method may be employed in which a sensor is incorporated in the apparatus and a test object is put into the apparatus, or a method in which the sensor is made small and the sensor is inserted into a test object (for example, a tissue or a cell).

The molecular sensor of the present invention comprises a ligand binding part of IP ₃ receptor and two kinds of fluorescent substances (for example, ECFP and EYFP). An example of the structure (SEQ ID NO: 1) is shown in FIG. In the amino acid sequence represented by SEQ ID NO: 1, ECFP is located at positions 21 to 259, EYFP is located at positions 899 to 1137, and the ligand binding site of the IP ₃ receptor is located at positions 265 to 868.
The IP ₃ receptor is a Ca ²⁺ channel that opens when IP ₃ binds, and IP ₃ specifically binds to the N-terminal portion thereof (Patent Document 2). As the IP ₃ receptor, a wide range of biological species such as chickens, Xenopus, Drosophila, starfish, nematodes and the like may be used, but in the present invention, mammals such as humans, mice and rats are used. It is preferable to use it. In addition, three subtypes of type 1 to type 3 are known for mammalian IP ₃ receptors, any of which may be used.
Region of IP ₃ receptors The IP ₃ binds specifically, for example, rat type 3IP ₃ receptors: the (Blondel et al, J. Biol Chem , 268... 11356-11363 (1993), L06096) The amino acid sequence is at least 226 to 578 (490 to 842 of SEQ ID NO: 1, Non-Patent Document 6 and Patent Document 1), preferably 1 to 578 (265 to 842 of SEQ ID NO: 1). In Examples described later, it has been confirmed that the 1st to 604th ones (265th to 868th of SEQ ID NO: 1) function, but it is thought that even shorter ones will function. That is, it is considered that one from the 1st to 225th positions (265th to 489th positions of SEQ ID NO: 1) to the 578th to 604th positions (842th to 868th positions of SEQ ID NO: 1) of this sequence is preferable.

Both ECFP (enhanced cyan fluorescent protein) and EYFP (enhanced yellow fluorescent protein) are mutants of jellyfish-derived green fluorescent protein (GFP). ECFP emits blue fluorescence with a maximum wavelength near 480 nm when irradiated with 425 nm excitation light, and EYFP emits yellow fluorescence with a maximum wavelength near 528 nm when irradiated with excitation light at 514 nm. Normally, EYFP does not emit fluorescence with excitation light of 425 nm, but when ECFP is nearby, it emits fluorescence by energy transfer from ECFP excited at 425 nm. This phenomenon is called fluorescence resonance energy transfer (FRET). Molecular sensors of the present invention, IP ₃ three-dimensional structure of the N-terminal portion of the receptor is changed by the binding of IP _3, that the result is FRET efficiency between the two fluorescent proteins decreases the fluorescence ratio changes We are using.
The ECFP and EYFP can be modified to improve the efficiency and pH stability of FRET, or the EYFP can be modified to shift the fluorescence wavelength to the longer wavelength side (for example, a 457 nm argon ion laser). ) Can be modified. In particular, modification of the acceptor EYFP moiety is effective in improving FRET efficiency. Further, by using a fluorescent pair other than ECFP and EYFP, various light sources can be used and FRET efficiency can be increased. In the present invention, as long as these two fluorescent proteins cause fluorescence resonance energy transfer (FRET), it is considered that it is also within the scope of the present invention to use a modified version of these two fluorescent proteins. .

Furthermore, in the present invention, the fluorescent protein is linked through a linker linked to the N-terminal C-terminus of the lP ₃ receptor ligand binding site, but the linker is not necessary as long as it does not interfere with each function. The fluorescent substance may be attached at any place other than the N-terminal or C-terminal of the lP ₃ receptor ligand binding site. The fluorescent substance that binds to a particular amino acid or amino acid sequence (amine-reactive dyes, carboxyl-reactive dyes, thiol-reactive dyes, F1AsH, ReAsH, Pro-Q, etc.) amino acid or its lP ₃ receptor ligand binding site An amino acid or amino acid sequence inserted at a specific site (tetracysteine motif, oligohistidine, etc.) is considered to be within the scope of the present invention.

As variants of EYFP, Q69K (for the purpose of improving pH stability), Q69M (for the purpose of improving stability against Citrine, pH, chlorine, and fluorescence fading), F64L / M153T / V163A / S175G ( super-YFP, aiming to improve stability against pH and chlorine and improving FRET efficiency.), F46L (to improve FRET efficiency), F46L / F64L / M153T / V163A / S175G (Venus, pH For the purpose of improving stability against chlorine and FRET efficiency) (Nagai et al. Nature Biotech., 20: 87-90 (2002); O. Griesbeck et al. J. Biol. Chem., 276: 29188-29194 (2001)).
As a modified EYFP, Phi-Yellow (manufactured by Evrogen JSC, Inc. for the purpose of improving pH stability and FRET detection efficiency) can also be used.
Further, the following combinations are possible. List each excitation wavelength (Ex) and fluorescence wavelength (Em).
EBFP / EGFP Ex 350-390nm: Em 420-480nm / 515-555nm
ECFP / DsRed Ex 400-460nm: Em 465-495nm / 565-595nm
EGFP / DsRed Ex 450-480nm: Em 485-510nm / 565-595nm
Sapphire / DsRed Ex 380-430nm: Em 485-510nm / 565-595nm
EYFP / HcRed-tandem Ex 460-490nm: Em 510-545nm / 640-680nm
Midoriishi-Cyan / Kusabira-Orange Ex 400-460nm: Em 465-510nm / 540-600nm
EBFP, ECFP, EGFP, EYFP (manufactured by Clontech) and Sapphire (manufactured by Aurora) are GFP mutants derived from Aequorea jellyfish, DsRed (manufactured by Clontech), HcRed-tandem (manufactured by Evrogen JSC), Midoriishi -Cyan and Kusabira-Orange (manufactured by the Institute of Medical Biology) are coral-derived fluorescent proteins.

In addition, as a variant of EYFP, a polypeptide having a sequence called tetracysteine motif (-Cys-Cys-Xaa-Xaa-Cys-Cys- (SEQ ID NO: 2); Xaa is an arbitrary amino acid) and a Fluorescein Arsenical Hairpin binder (FlAsH , Manufactured by Panvera) (BAGriffin et al. Science 281: 269-271 (1998)). FlAsH is a derivative of fluorescein, a green fluorescent dye, and has the property of binding specifically to the tetracysteine motif. When using this tetracysteine motif and FlAsH complex, first, a fusion protein in which EYFP is replaced with a polypeptide containing the tetracysteine motif is expressed. When FlAsH-EDT2 (Panvera) is allowed to act on this, a complex of the polypeptide containing the tetracysteine motif and FlAsH is formed by a chemical reaction.
Similarly, fluorescent dyes that bind to functional groups such as oligohistidine and amino groups, carboxyl groups, and thiol groups of amino acids can be chemically bonded.

In addition, Ace-Green and Cop-Green (Evrogen JSC) can be used as alternatives to EGFP, and HcRED-tandem (Evrogen JSC) can be used as alternatives to DsRed.
As shown in FIG. 1, the molecular sensor of the present invention comprises a ligand binding part of IP ₃ receptor and two kinds of fluorescent substances (ECFP, EYFP, etc.). These two types of fluorescent substances may be exchanged, and a linker composed of amino acids of 1 residue or more, preferably about 4 to 30 residues, may be inserted between these constituent parts.
In addition, this molecular sensor may have a localization signal, and by immobilizing to a specific site, it is considered that fluorescence change is likely to occur, and quantitative measurement of IP ₃ concentration is facilitated. The binding position of the localization signal in the molecular sensor may be either N-terminal or C-terminal, but the N-terminal is preferable.
Examples of localization sites include cell membrane, mitochondria, cytoskeleton, nucleus, endoplasmic reticulum, etc.In order to localize the IP ₃ sensor to the cell membrane as shown in the examples, the neuromodulin balmitoylation domain is used. Twenty amino acids may be added to the N-terminus.
Furthermore, the molecular sensor may include an amino acid sequence for protein purification such as FLAG, His-tag, strep-tag, GST, HA-tag, and c-myc, an amino acid sequence serving as a substrate for protease, and the like.
Further, it preferably has a Kozak sequence (Kozak sequence; CGCCACCATGC) upstream of the start codon of the molecular sensor gene.

By utilizing the molecular sensor of the present invention, it is possible to know changes in the concentration of IP ₃ in cells, animals and plant tissues. As a method for introducing the molecular sensor into the cell, any known method may be used. The molecular sensor (protein) may be directly introduced into the cell, or DNA encoding the protein may be introduced into the cell. May be expressed. As a particularly reliable method, various cells, animals and plants can be transformed by incorporating DNA encoding the molecular sensor constructed as described above into an appropriate vector. As this vector, a plasmid vector, a viral vector, Agrobacterium or the like can be used. In order to introduce the recombinant vector into cells, known methods such as lipofection method, calcium phosphate method, microinjection method, proplast fusion method, electroporation method, DEAE dextran method, gene introduction by Gene Gun can be used. Alternatively, as a method for intracellular expression of the fusion protein, a transgenic animal or plant (transgenic animal or transgenic plant) in which the fusion protein gene is incorporated into chromosomal DNA can also be produced. Production of transgenic animals and transgenic plants can also be performed by known methods. Further, in the production, the fusion gene may be any may be inserted into the site, or endogenous lP ₃ gene homologous recombination of the chromosomal DNA. Such transgenic animals (mouse, zebrafish, etc.) and transgenic plants (tobacco, Arabidopsis, rice, etc.) can quantitate lP ₃ concentrations in an in vivo system, and elucidate the function of IP ₃ receptors. It is highly useful for elucidating the pathophysiology caused by disorders of the IP ₃ -Ca ²⁺ system, establishing treatments and diagnostic methods, and screening for drugs.
In addition, cells obtained from these transgenic animals and transgenic plants can be used for drug screening and the like. Furthermore, by using a molecular sensor, it is possible to easily measure the concentration of 1P ₃ in a solution as compared with the conventional method, and it is also possible to create a measurement kit and a measurement device for that purpose.

  Further, the molecular sensor of the present invention can be used in a solution as it is, or can be used by being immobilized on a suitable substrate.

  The molecular sensor as described above is irradiated with light corresponding to the absorption wavelength of a fluorescent protein that is a donor (for example, ECFP or a variant thereof). The wavelength of the irradiation light varies depending on the degree of modification, but is 350 to 500 nm, preferably 400 to 460 nm. When non-modified ECFP is used, it is preferable to use excitation light of 420 to 430 nm. As the light source, a light source having broad ultraviolet light or visible light in a desired wavelength range using a filter or a spectroscope may be used, or monochromatic light such as a laser may be used. When using a laser light source, helium cadmium laser (442nm) is common, but blue diode laser (405nm), argon ion laser (457nm), LD pumped solid-state laser (430nm) Etc. may be used. In the case of the two-photon excitation method, a pulse laser of around 800 nm may be used.

In the present invention, each fluorescence from a fluorescent protein (for example, ECFP or a variant thereof) as a donor and the other fluorescent protein (for example, EYFP or a variant thereof) is measured. That is, changes in fluorescence intensity due to fluorescence resonance energy transfer (FRET) of fluorescence at 400 to 515 nm, preferably 465 to 495 nm and 515 to 600 nm, preferably 522 to 548 nm are measured. That is, if the FRET efficiency decreases due to the influence of IP ₃ , the fluorescence intensity of ECFP or a variant thereof increases, and the fluorescence intensity of EYFP or a variant thereof decreases. Therefore, if the extent of these increases and decreases is measured Good. These changes because it depends on the concentration of IP _3, it is possible to estimate the concentration of IP ₃ from these changes. Any method may be used for the treatment of these two kinds of fluorescence intensities. The simplest method is to measure the ratio of each fluorescence intensity from ECFP or a variant thereof and EYFP or a variant thereof, and calculate the ratio of the ratio at a case where the IP ₃ concentration is 0 and several known IP ₃ concentrations. By calculating the difference and creating a calibration curve between them, the IP ₃ concentration can be determined from the fluorescence intensity ratio data.
It is also possible to search for signal molecules and drugs that affect the IP ₃ production system and metabolic system in the cell, and consequently affect the IP ₃ concentration. Furthermore, using this molecular sensor, it is possible to detect a drug that activates or suppresses the IP ₃ receptor and to measure its concentration.

Since IP ₃ is involved in the generation of Ca ²⁺ signals in various cells, this fusion protein is expected to be used in a wide range of biomedical research. In particular, the IP ₃ sensor created this time is encrypted with DNA, so it can be introduced into various cells. In addition, by introducing this gene into a fertilized egg, it is possible to create a transgenic animal that expresses the IP ₃ sensor in a whole body organ or an arbitrary organ. If such an animal is used, it can be expected to measure changes in intracellular IP ₃ concentration in living tissues and animals, and it is thought that it will bring about a great progress in elucidating various physiological functions and pathologies.

The following examples illustrate the invention, but are not intended to limit the invention.

pEYFP-N1 (Clontech, FIG. 2) was digested with BamH1 and Xba1 to prepare a DNA fragment containing the EYFP gene.
Moreover, pECFP-C1 (Clontech, FIG. 3) was cut with BamH1 and Xba1, and a DNA fragment containing the EYFP gene was ligated thereto.
Next, the fusion gene vector of ECFP and EYFP is cleaved with BspE1 and BamH1 to remove 60 bases up to the 1331-1390th position of the vector (Fig. 3), and there are BspE1, Xho I, Bgl II, Sal I A synthetic DNA fragment (SEQ ID NO: 3, linker part) containing the restriction enzyme site of Bam H1 was inserted (pCY-N, FIG. 4).
pCY-N was cleaved with BsrGI, and a DNA fragment in which a part of ECFP, MCS and EYFP genes were linked was excised.
Similarly, pECFP-mem (Clontech, FIG. 5) was digested with BsrGI, and a DNA fragment excised from pCY-N was inserted therein (mCY-N, FIG. 6).
Furthermore, mCY-N was cleaved with Eco47 III / Sma I to separate and remove 62 bases upstream of the balnesylation domain (membrane localization signal) and fused as they were. As a result, an unnecessary restriction enzyme cleavage site of the untranslated site was removed, and an ECFP-EYFP fusion protein gene vector (mCY, FIG. 7) in which a valnesylated domain was added to the 5 ′ end was prepared.

Next, primers (sense primer (SEQ ID NO: 4) and antisense primer (SEQ ID NO: 5)) were designed from the gene sequence of rat IP ₃ receptor (type 3), and a rat parotid gland cDNA library was used as a template. By PCR reaction, Xho at the 5 ′ end and 3 ′ end of 1.8 kb DNA (IP ₃ R-N1.8, 793-2604 of SEQ ID NO: 6) encoding a polypeptide containing the ligand binding site of IP ₃ receptor. A DNA fragment to which an I cleavage site was added was prepared. This IP ₃ R-N1.8 was 71.7% homologous to the known ligand binding site of the mouse IP ₃ receptor (type 1) (Receptor and Channels, 2: 2-22 (1994)).
This PCR product was inserted into a TA cloning vector, amplified, and then excised with XhoI. The excised DNA fragment was inserted into mCY cut with XhoI to prepare an IP ₃ sensor expression vector (mCY-IP ₃ R-N1.8).
FIG. 8a shows the restriction enzyme map of the mCY-IP ₃ R-N1.8 vector (SEQ ID NO: 7) and the position of the molecular sensor (SEQ ID NO: 6). FIG. 8b shows the location of genes and restriction enzyme sites in the molecular sensor. In this mCY-IP ₃ R-N1.8 vector (SEQ ID NO: 7), positions 617 to 4027 are molecular sensors (SEQ ID NO: 6). In the base sequence of SEQ ID NO: 6, positions 1 to 60 are membrane localization domains. , is 61 to 777 th ECFP, seven hundred and seventy-eight to seven hundred and ninety-two th 1,793～2604 th linker IP ₃ receptor ligand binding site, from 2605 to 2694 th 2,2695～3411 th linker encoding EYFP.

SH-SY5Y cells (obtained from DSMZ (Deutsche Sammlung von Mikroorganismen und Zellkulturen)) are cultured in an experimental chamber with a volume of approximately 100 μL, and molecular sensor genes are introduced into the cells using Lipofectamine 2000 (Invitrogen). The molecular sensor was expressed. When this chamber was set on a fluorescence microscope and observed, the localization of the molecular sensor to the cell membrane was observed. This is shown in FIG. When the cells were excited with 430 nm light, ECFP fluorescence of 480 nm and EYFP fluorescence of 535 nm were observed.
In order to make IP ₃ act directly on this molecular sensor, the cells in the chamber were perforated with saponin. For cell perforation, cells were exposed to an intracellular fluid-like medium (ICM; 125 mM KCl, 25 mM NaCl, 1 mM EGTA, 330 μM CaCl ₂ , pH 7.3) containing 100 μg / ml saponin (chamber after the perforation). The liquid inside was replaced with ICM without saponin). Molecular sensors were localized to the cell membrane even after perforating the cells.

The SH-SY5Y cells into which the molecular sensor prepared in Example 1 was introduced were excited with light of 430 nm, and the fluorescence at 480 nm which is the fluorescence of ECFP and the fluorescence at 535 nm which is the fluorescence of EYFP was observed.
Nikon inverted microscopes, Hamamatsu Photonics image analyzers, W-viwe optical system, and image analyzer software (AQUACOSMOS) were used as experimental devices.
A sample (SH-SY5Y cells expressing a molecular sensor) was set on a fluorescence microscope and irradiated with light of 425 nm. The fluorescence from the sample was separated into two optical paths by a 485 nm dichroic mirror, and only the fluorescence at 480 ± 15 nm and 535 ± 12.5 nm was extracted by a fluorescent filter attached to each optical path. Each fluorescence image was recorded simultaneously with a cooled CCD camera, and a fluorescence ratio obtained by dividing fluorescence at 480 nm (ECFP) by fluorescence at 535 nm (EYFP) was calculated using image analysis software.

Replacing perforated cells perforated with saponin with an intracellular liquid-like solution (ICM) containing IP ₃ at various concentrations (0.03-10 μM), the fluorescence ratio (480 nm / 535 nm) of the molecular sensor depends on the IP ₃ concentration. An increase was observed (FIG. 10). The change in fluorescence ratio that occurred with 10 μM IP ₃ was maximized, and the concentration of IP ₃ that caused a 50% change in fluorescence ratio (EC50) was about 200 nM.
Adenophostin A, a higher affinity agonist of IP ₃ receptor, caused an increase in fluorescence ratio equivalent to IP ₃ at about 1/10 of its concentration. In contrast, inositol 1,3,4 triphosphate and inositol 4,5 diphosphate showed almost no change in fluorescence ratio. High concentrations of inositol 1,3,4,5 tetraphosphate slightly increased the fluorescence ratio (FIG. 11). These properties were in good agreement with the properties of the native IP ₃ receptor reported so far.
As a control experiment, a similar experiment was performed on cells expressing mCY, but no change in the fluorescence ratio was observed.
From these results, it was confirmed that this fusion protein can be used as a highly sensitive molecular sensor with high IP ₃ specificity.

Next, by replacing the solution in the chamber containing SH-SY5Y cells expressing this molecular sensor with Hanks-Hepes solution containing 10 μM and 100 μM acetylcholine, the cells were stimulated with acetylcholine to obtain a fluorescence ratio (480 nm / 535 nm). An increase was observed, and the fluorescence ratio returned to its original value when replaced with Hanks-Hepes solution containing no acetylcholine (FIG. 12). When this change (difference) in the fluorescence ratio is compared with a calibration gland (FIG. 13) prepared by applying a known concentration of IP ₃ to perforated cells, the intracellular IP ₃ concentration of SH-SY5Y cells upon stimulation with acetylcholine is about Calculated as 0.3 μM.
From this result, it was confirmed that the intracellular IP ₃ concentration can be accurately quantified by measuring the change in the fluorescence intensity ratio of the molecular sensor of the present invention.

In order to improve the pH stability and FRET efficiency of IP ₃ molecular sensors prepared in Example 1 to prepare a pH-stable IP ₃ molecules sensors replacing the EYFP a fluorescent acceptor YFP mutants (Figure 14). These YFP mutants are EYFP 46th and 64th phenylalanine to leucine (F46L, F64L), 153rd methionine to threonine (M153T), 163rd valine to alanine (V163A), 175th serine Is replaced with glycine (S175G), which is known to increase stability against pH and chlorine concentration and increase fluorescence intensity (Nagai et al. Nature Biotech., 20: 87-90 (2002) ).
First, a primer (SEQ ID NO: 8) and an antisense primer (SEQ ID NO: 9) were designed, and pEYFP-N1 amino acid substitution (F46L) was performed using QuikChange II XL Site-Directed Mutagenesis Kit (Strategene). . Next, using the primer (SEQ ID NO: 10) and the antisense primer (SEQ ID NO: 11), amino acid substitution of (F64L) was performed with QuikChange II XL Site-Directed Mutagenesis Kit. Furthermore, amino acid substitution of (M153T / V163A / S175G) was performed using a primer (SEQ ID NO: 12) and an antisense primer (SEQ ID NO: 13) to prepare a YFP mutant.

Next, a primer (SEQ ID NO: 14) and an antisense primer (SEQ ID NO: 15) are designed and subjected to a PCR reaction using mCY-IP ₃ R-N1.8 as a template, membrane localization signal, ECFP, IP ₃ receptor ligand A DNA fragment encoding the binding site and linker polypeptide was generated. This PCR product was inserted into a TA cloning vector, amplified, and then excised with NheI and EcoRI. A vector containing the YFP displacement gene was cleaved with NheI and EcoRI, and a DNA fragment excised from the TA cloning vector was inserted to create a pH stable IP ₃ molecular sensor (mCYv-IP ₃ R-N1.8). .
FIG. 15 shows the IP ₃ molecular sensor (mCY-IP ₃ R-N1.8) not introduced with displacement and the pH-stable IP ₃ molecular sensor (mCYv-IP ₃ R-) with displacement introduced in Example 1. N1.8) changes in fluorescence ratio using saponin perforated cells. EYFP used in mCY-IP ₃ R-N1.8 has a large increase in fluorescence ratio (480nm / 535nm) due to the decrease in fluorescence intensity due to the decrease in pH (a). In mCYv-IP ₃ R-N1.8, it was confirmed that the change in fluorescence ratio due to pH was suppressed to about 1/3 (b).
Furthermore, when the reactivity to IP ₃ is compared using saponin perforated cells (FIG. 16), the molecular sensor after mutation introduction (b) changes depending on IP ₃ compared to the molecular sensor (a) before mutation introduction. It was confirmed that the ratio of the fluorescence ratio was enhanced about 1.5 times.

There are _three types of mammalian IP ₃ receptors, type 1 to type 3, and types 1 and 2 are known to have higher affinity for IP ₃ than type 3 (Miyakawa et al. EMBO J., 18: 1303-1308 (1999)). Therefore, in order to further enhance the IP ₃ sensitivity of the pH stable IP ₃ molecular sensor (mCYv-IP ₃ R-N1.8) prepared in Example 4, it corresponds to the 1-604th amino acid of the type ₃ IP ₃ receptor. It created a molecular sensors that substituting amino acids up to 265-868 in SEQ ID NO: 1 in the ligand binding portions of the type 1IP ₃ receptor and type 2IP ₃ receptor (1-604 amino acid) that.
Primers (sense primer (SEQ ID NO: 16) and antisense primer (SEQ ID NO: 17)) were designed from the gene sequence of rat IP ₃ receptor (type 1), and PCR reaction was performed using rat parotid gland cDNA library as a template. A DNA fragment was prepared by adding a XhoI cleavage site to the 5 ′ end and 3 ′ end of a 1.8 kb DNA encoding a polypeptide containing a ligand binding site (up to 1-604th) of the type 1 IP ₃ receptor. This PCR product was inserted into a TA cloning vector, amplified, and then excised with XhoI. The pH-stable IP ₃ molecule sensor (mCYv-IP ₃ R-N1.8) prepared in Example 4 was cleaved with Xho I, and a DNA fragment excised from the TA cloning vector was inserted to obtain a highly sensitive IP ₃ molecule. Sensor type 1 (mCYv-IP ₃ R1) was created.
Similarly, primers (sense primer (SEQ ID NO: 16), antisense primer (SEQ ID NO: 18)) were designed, and the ligand binding site of type 2 IP ₃ receptor was determined by PCR reaction using rat parotid gland cDNA library as a template. A DNA fragment was prepared by adding XhoI cleavage sites to the 5 ′ end and 3 ′ end of 1.8 kb DNA encoding the polypeptide to be contained. This PCR product was inserted into a TA cloning vector, amplified, and then excised with XhoI. The excised DNA fragment was inserted into a pH-stable IP ₃ molecule sensor cleaved with Xho I to prepare a highly sensitive IP ₃ molecule sensor type 2 (mCYv-IP ₃ R2).

Substituting glutamine for the 441st arginine of the ligand binding site of type 1 IP ₃ receptor is known to increase the affinity for IP ₃ (Yoshikawa et al., J. Biol. Chem., 271: 18277-18284). (1996)). Similar affinity improvement of the fact that is expected to occur in type 2IP ₃ receptor and type 3IP ₃ receptor, pH stabilized IP ₃ molecular sensors _{(mCYv-IP 3 R-N1.8} ) and highly sensitive IP _In order to further enhance the IP ₃ sensitivity of the trimolecular sensor type 2 (mCYv-IP ₃ R2), amino acid substitution at the ligand binding site of the molecular sensor was performed.
A primer (SEQ ID NO: 19) and an antisense primer (SEQ ID NO: 20) are designed, and the 704th arginine of SEQ ID NO: 1 of mCYv-IP ₃ R-N1.8 is glutamine using the QuikChange II XL Site-Directed Mutagenesis Kit. The high-sensitivity IP ₃ molecule sensor type 3 (mCYv-IP ₃ R3S) was created.
Similarly, a primer (SEQ ID NO: 21) and an antisense primer (SEQ ID NO: 22) are designed, and the 705th arginine of mCYv-IP ₃ R2 is replaced with glutamine using QuikChange II XL Site-Directed Mutagenesis Kit. Type IP ₃ molecule sensor type 2S (mCYv-IP ₃ R2S) was prepared.

PH stable IP ₃ molecule sensor (mCYv-IP ₃ R-N1.8) prepared in Example 4, high sensitivity IP ₃ molecule sensor type 1 (mCYv-IP ₃ R1) prepared in Example 5 and high Sensitive IP ₃ molecule sensor type 2 (mCYv-IP ₃ R2) and high sensitivity type IP ₃ molecule sensor type 3 (mCYv-IP ₃ R3S) and high sensitivity type IP ₃ molecule sensor type 2S created in Example 6 The reactivity of (mCYv-IP ₃ R2S) was compared with that of the molecular sensor (mCY-IP ₃ R-N1.8) before the mutagenesis prepared in Example 1. That is, SH-SY5Y cells into which genes encoding these molecular sensors were introduced were perforated with saponin, and the change in fluorescence ratio due to 10 nM to 10 μM IP ₃ was analyzed.
The minimum IP ₃ concentration that causes a change in the fluorescence ratio of the molecular sensor before mutagenesis was 100 nM, whereas the high sensitivity type 1, high sensitivity type 2 and high sensitivity type 2S had an IP ₃ of 10 nM. A clear increase in the fluorescence ratio was observed. In the high-sensitivity type 2, high-sensitivity type 2S, and high-sensitivity type 3, the change in fluorescence ratio due to 100 nM IP ₃ increased 4 to 6 times (FIG. 17). From these results, it was confirmed that the high-sensitivity IP ₃ molecular sensor type 1, type 2, type 2S, and type 3 all have increased reactivity to low concentrations of IP ₃ .

The molecular sensor of the present invention can be used to search for drugs that act on IP ₃ receptors, drugs that act on IP ₃ production systems, or IP ₃ degradation systems. In that case, a control molecule that has almost the same structure as a molecular sensor but does not have an affinity for IP ₃ is useful as a means for ascertaining whether or not the action of these drugs is specific.
It is known that the affinity for IP ₃ disappears when lysine at position 508 in the ligand binding site of type 1 IP ₃ receptor is substituted with alanine (Yoshikawa et al., J. Biol. Chem., 271: 18277- 18284 (1996)). Since the similar loss of affinity is expected to occur in the type ₃ IP ₃ receptor, amino acid substitution was performed at the ligand binding site of the pH stable IP ₃ molecular sensor (mCYv-IP ₃ R-N1.8). . Design a primer (SEQ ID NO: 23) and antisense primer (SEQ ID NO: 24), and replace 771st lysine of mCYv-IP ₃ R-N1.8 with alanine using QuikChange II XL Site-Directed Mutagenesis Kit. A control molecule (mCYv-IP ₃ R3C) was created.
When SH-SY5Y cells into which the gene encoding this molecule was introduced were perforated with saponin and the change in fluorescence ratio due to IP ₃ was analyzed, the change in fluorescence ratio did not change even when the maximum concentration (10 μM) of IP ₃ was added. It was not recognized at all (FIG. 18). From the results, the molecule can be used as a control molecule having no affinity for IP ₃ was confirmed.

It is a figure which shows the example of the structure of the molecular sensor of this invention. m is a cell membrane localization signal, E is an amino acid sequence that is specifically cleaved by enterokinase, ratIP ₃ R3 (1-604) is the ligand binding site of IP ₃ receptor, and ECFP and EYFP are fluorescent proteins. The enterokinase cleavage site was used to calculate FRET efficiency. It is a figure which shows the restriction enzyme map of pEYFP-N1 (4733bp) containing fluorescent protein EYFP gene. It is a figure which shows the restriction enzyme map of pECFP-C1 (4731bp) containing fluorescent protein ECFP gene. It is a figure which shows the restriction enzyme map of pCY-N (5490bp). It is a figure which shows the restriction enzyme map of pECFP-mem (4793bp). It is a figure which shows the restriction enzyme map of mCY-N (5609bp). It is a figure which shows the restriction enzyme map of mCY (5547bp). mCY-IP ₃ R-N1.8 vector (a, 7365bp) is a diagram showing a molecular sensor (b, 4311bp) restriction enzyme map of. a indicates the position of the IP ₃ molecular sensor gene and the restriction enzyme cleavage site in the expression vector, and b indicates the position of the component of the molecular sensor gene. The BsrG I cleavage sites of 1386 and 4032 were used when inserting part of p-CY-N into the ECFP-mem vector. The untranslated Eco47 III and Sma I cleavage sites disappeared with the creation of mCY. 1403 and 3221 Xho I cleavage sites were used to insert the IP ₃ R-N1.8 gene into mCY. It is a fluorescence-microscope image after SH-SY5Y cell which expressed the molecular sensor is saponin-treated. It shows that the molecular sensor is distributed in the cell membrane. The scale bar in the photograph is 10 μm. Is a diagram showing changes in fluorescence ratio molecular sensors by IP _3. The change in fluorescence ratio (480 nm / 535 nm) is shown when cells expressing a molecular sensor are perforated with saponin and various concentrations of IP ₃ are added. The vertical axis represents the fluorescence ratio, and the horizontal axis represents time. The excitation wavelength was 425 nm. Cells expressing molecular sensors are perforated with saponin, and various concentrations of inositol 1,4,5 triphosphate (IP ₃ ), inositol 4,5 diphosphate (IP ₂ ), inositol 1,3,4 triphosphate Rate of change in fluorescence ratio (480 nm / 535 nm) when acid (1,3,4-IP ₃ ), inositol 1,3,4,5 tetraphosphate (IP ₄ ), adenophostin A (AdenoA) is added Indicates. The change due to IP ₃ of 10 μM was taken as 100%, and the results were expressed as the mean ± standard error of the experimental results of 6-10 cases. The vertical axis represents the rate of change with respect to the maximum response, and the horizontal axis represents the drug concentration. Is a diagram showing an example of measurement of intracellular IP ₃ concentration by molecular sensors. The change of the fluorescence ratio (480 nm / 535 nm) when the cell which expressed the molecular sensor was stimulated with 10 μM and 100 μM acetylcholine (ACh) is shown. The vertical axis shows the amount of change (difference) when the fluorescence ratio during no stimulation is 0, and the horizontal axis shows time. It is a diagram illustrating an example of a calibration curve of the change in fluorescence ratio (difference) IP ₃ concentration relationship. The vertical axis indicates the amount of change (difference) when the fluorescence ratio during no stimulation is 0, and the horizontal axis indicates the IP ₃ concentration. It shows the pH stable IP ₃ molecular sensors. It is a figure which shows the influence with respect to pH of the fluorescence intensity of a molecular sensor. a represents the IP ₃ molecule sensor of Example 1 (mCY-IP ₃ R-N1.8), and b represents the pH stable IP ₃ molecule sensor of Example 4 (mCYv-IP ₃ R-N1.8). It is a figure that shows the reactivity against IP ₃ of molecular sensors. a represents the IP ₃ molecule sensor of Example 1 (mCY-IP ₃ R-N1.8), and b represents the pH stable IP ₃ molecule sensor of Example 4 (mCYv-IP ₃ R-N1.8). Is a diagram illustrating an IP ₃ susceptibility of molecular sensors. The vertical axis shows the change rate (%) of the relative fluorescence ratio (R0; 480 nm / 535 nm) to the reaction with the maximum concentration of IP ₃ (10 μM), and the horizontal axis shows the concentration of IP ₃ added (nM). Control molecule is a diagram showing that do not respond to IP _3. The vertical axis represents the fluorescence ratio (480 nm / 535 nm), and the horizontal axis represents time.

Claims (13)

A molecular sensor comprising a ligand binding part of an IP ₃ receptor and two fluorescent substances that cause fluorescence resonance energy transfer (FRET), wherein the ligand binding part of the IP ₃ receptor has the following (1) or (2 ) A molecular sensor comprising any of the polypeptides.
(1) A polypeptide comprising the amino acid sequence from any of the amino acid sequence 265 to 489 to any one of the 842 to 868 of the amino acid sequence represented by SEQ ID NO: 1 (2) In the polypeptide of (1), 1 or a number A polypeptide comprising an amino acid sequence in which one amino acid is substituted and having affinity for inositol 1,4,5 triphosphate The molecular sensor according to claim 1, wherein the fluorescent substance is composed of a fluorescent protein ECFP or a variant thereof and a fluorescent protein EYFP or a variant thereof. Furthermore, the molecular sensor of Claim 1 or 2 which has a localization signal. The fluorescent protein ECFP is composed of the polypeptide of (3) or (4), and the fluorescent protein EYFP is composed of the polypeptide of (5) or (6). The molecular sensor according to one item.
(3) Polypeptide (4) consisting of amino acid sequences 21 to 259 of the amino acid sequence represented by SEQ ID NO: 1 (4) In the polypeptide of (3), one or several amino acids have been deleted, substituted or added A polypeptide comprising an amino acid sequence and emitting light having a peak at 465 to 495 nm (5) Polypeptide of a polypeptide (6) (5) comprising an amino acid sequence from 899 to 1137 of the amino acid sequence represented by SEQ ID NO: 1 A polypeptide comprising an amino acid sequence in which one or several amino acids are deleted, substituted, or added, and emitting light having a peak at 522 to 548 nm. DNA encoding the molecular sensor according to any one of claims 1 to 4. A recombinant vector comprising the DNA according to claim 5. A transformant (excluding humans) transformed with the recombinant vector according to claim 6. A cell (excluding human) having the molecular sensor according to any one of claims 1 to 4 in the cell. An animal (excluding human) or a plant having the molecular sensor according to any one of claims 1 to 4 in the body. The transformant according to claim 7, the cell according to claim 8, or the animal or plant according to claim 9 is irradiated with light of 350 to 500 nm, and fluorescence at 400 to 515 nm and 515 to 600 nm is measured. And a method for estimating the concentration of inositol 1,4,5 triphosphate in the transformant or the cell using these fluorescence intensities as an index. An unknown drug is introduced into the transformant according to claim 7, the cell according to claim 8, or the animal or plant according to claim 9, and irradiated with light of 350 to 500 nm, to give 400 to 515 nm And measuring fluorescence at 515 to 600 nm and screening for ligands or inhibitors of the IP ₃ receptor using these fluorescence intensities as indices. An IP ₃ detector comprising the molecular sensor according to claim 1. The apparatus according to claim 12 is brought into contact with the test object, irradiated with light of 350 to 500 nm, fluorescence at 400 to 515 nm and 515 to 600 nm is measured, and the test object is measured using these fluorescence intensities as indices. Of estimating the concentration of inositol 1,4,5 triphosphate therein.