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JP4710008B2 - Method for producing cultured myocytes with high metabolic capacity - Google Patents

Method for producing cultured myocytes with high metabolic capacity Download PDF

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JP4710008B2
JP4710008B2 JP2005122148A JP2005122148A JP4710008B2 JP 4710008 B2 JP4710008 B2 JP 4710008B2 JP 2005122148 A JP2005122148 A JP 2005122148A JP 2005122148 A JP2005122148 A JP 2005122148A JP 4710008 B2 JP4710008 B2 JP 4710008B2
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展 神崎
英明 藤田
拓 根建
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Description

本発明は、高い収縮能力及び高い代謝能を有する筋管細胞の作製方法、該方法の使用に特に適した培養装置、及び、筋管細胞を用いるインスリン依存的な糖取り込み能の測定方法等に関する。   The present invention relates to a method for producing myotube cells having high contractile ability and high metabolic ability, a culture apparatus particularly suitable for use of the method, a method for measuring insulin-dependent sugar uptake ability using myotube cells, and the like. .

筋肉は運動機能をつかさどるだけでなく、最大のインスリン標的組織として血糖のホメオスタシス維持に必須の役割を果たしている。現在爆発的に増加している2型糖尿病では、インスリン刺激に依存した筋肉への「糖の取り込み」が著しく減弱している。そして、適度な運動刺激は効果的にその病態を改善できることが知られており、臨床の現場でも運動療法は行われているが、その分子機序の詳細は不明である。   Muscles not only control motor function, but also play an essential role in maintaining homeostasis of blood glucose as the largest insulin target tissue. In type 2 diabetes, which is currently increasing explosively, “sugar uptake” into muscles that is dependent on insulin stimulation is markedly attenuated. And it is known that moderate exercise stimulation can effectively improve the pathological condition, and exercise therapy is also performed in the clinical field, but details of the molecular mechanism are unknown.

筋肉の運動すなわち筋細胞の収縮伸展は、メカニカルな刺激に加え、大きなエネルギー消費を伴う。そして、生体内ではこの両者の複合的な刺激が高い糖代謝能を所有する「健康な筋細胞」を作り上げ、その適正なインスリン反応性を維持している。しかしながら、培養系において筋細胞の収縮活動を十分活発に維持することは難しく、生体を模した優れた培養筋細胞系、特に代謝能の研究に適したものは存在しない。そのため、従来、筋細胞に対する薬剤の効果などは、(1)動物実験あるいは動物から採取した筋組織を用いて行うか、又は、(2)十分に発達していない培養筋細胞株を用いて行われてきた。   Muscle movement, ie, muscle cell contraction and extension, is accompanied by significant energy consumption in addition to mechanical stimulation. And in the living body, it has created a “healthy muscle cell” possessing a high ability of glucose metabolism due to the combined stimulation of both, and maintains its proper insulin responsiveness. However, it is difficult to maintain the contraction activity of muscle cells sufficiently in a culture system, and there is no excellent cultured muscle cell system that mimics the living body, particularly suitable for studying metabolic capacity. Therefore, conventionally, the effect of a drug on muscle cells is performed by (1) animal experiments or using muscle tissue collected from animals, or (2) using cultured muscle cell lines that are not sufficiently developed. I have been.

筋組織は運動することによりその高い代謝能を発揮するため、動物から採取した筋組織を用いる場合には、筋細胞の代謝能におよぼす薬剤の効果を評価するためには、動物をトレッドミル上で無理矢理に走らせたり、水槽の中で長時間泳がせるなどの方法が主であった。また、実験動物から採取した筋組織に電極をつなぎ、電気パルス刺激にて収縮活動させてサンプルを得ていた。これらの動物実験は倫理的な問題点や、多数の薬剤のスクリーニングには不向きであるという問題点がある。   Since muscle tissue exerts its high metabolic capacity by exercising, when using muscle tissue collected from animals, to evaluate the effects of drugs on the metabolic capacity of muscle cells, animals are placed on a treadmill. The main method was to force it to run or to swim in the aquarium for a long time. In addition, an electrode was connected to muscle tissue collected from an experimental animal, and contraction was performed by electrical pulse stimulation to obtain a sample. These animal experiments have ethical problems and are unsuitable for screening many drugs.

一方、生体を模した優れた培養細胞系は薬剤のスクリーニングに非常に大きな戦力となる。しかしながら、収縮伸展するという筋細胞の特性を考慮した培養筋細胞系は乏しく、通常の培養条件で得られる培養筋細胞はほとんど収縮能力が発達していない。そのため、非特許文献1や非特許文献2にあるように高い代謝能を有するには至らず、生体の筋を模しているとは言い難く、代謝能の研究には全く不適であった。   On the other hand, an excellent cultured cell system simulating a living body is a very powerful force for drug screening. However, there are few cultured muscle cell systems that take into consideration the characteristics of muscle cells that contract and extend, and cultured muscle cells obtained under normal culture conditions have hardly developed contractile ability. Therefore, as described in Non-Patent Document 1 and Non-Patent Document 2, it does not have a high metabolic capacity, it is difficult to say that it imitates a muscle of a living body, and it is completely unsuitable for research on metabolic capacity.

更に、特許文献1には、筋芽細胞にパルス波による電気刺激を与えて自動収縮能を有する筋細胞を得る方法が記載されている。又、特許文献2には、上下方向の電流を流す細胞培養措置及び細胞培養方法が記載されている。   Furthermore, Patent Document 1 describes a method for obtaining a myocyte having an automatic contraction ability by applying electrical stimulation with a pulse wave to a myoblast. Patent Document 2 describes a cell culture method and a cell culture method in which a current in the vertical direction is passed.

しかしながら、これらに記載の細胞培養方法でも未だ取り込み測定等の代謝能の研究に適した筋細胞を作製することに成功してはいない。又、従来の代謝能の測定条件は培養筋細胞に適したものではなかった。
Biochem. Pharmacol.、2003年、第65巻, 249〜257頁 Am. J. Physiol. (Endoclinol Metab)、2002年、第283巻、E514〜524頁 特開2005−27501 特開2003−225
However, the cell culture methods described in these documents have not yet succeeded in producing myocytes suitable for studying metabolic capacity such as uptake measurement. Further, the conventional measurement conditions for metabolic capacity are not suitable for cultured muscle cells.
Biochem. Pharmacol., 2003, 65, 249-257 Am. J. Physiol. (Endoclinol Metab), 2002, 283, E514-524 JP-A-2005-27501 JP 2003-225 A

本発明の目的は、高い代謝能やインスリン反応性を有する優れた培養筋細胞を作製する方法を提供し、更に、その細胞を用いる高感度な代謝能の測定方法を提供することである。更に、このような高度発達型培養筋細胞を、そのまま多数の薬剤の活性評価系へとスムースに移行させることが可能な培養系・培養装置を提供すること目的としている。   An object of the present invention is to provide a method for producing excellent cultured muscle cells having high metabolic ability and insulin reactivity, and further to provide a highly sensitive method for measuring metabolic ability using the cells. It is another object of the present invention to provide a culture system and a culture apparatus capable of smoothly transferring such highly developed cultured muscle cells as they are to a number of drug activity evaluation systems.

本発明者は、筋芽細胞の培養において、培養液の状態(栄養素、酸素、及び老廃物の除去等)を最適化し、且つ、適切な電気パルスを負荷しながら分化誘導することにより、代謝能の評価に適した高度発達型培養筋細胞を作製することが可能であることを見出し、本発明を完成した。   The present inventor optimizes the state of the culture solution (removal of nutrients, oxygen, waste products, etc.) in the culture of myoblasts, and induces differentiation while loading an appropriate electric pulse, thereby It was found that highly developed cultured muscle cells suitable for the evaluation of the above could be prepared, and the present invention was completed.

即ち、本発明は以下の態様にかかる。
1.(1)筋芽細胞を培養する工程、(2)筋芽細胞を高アミノ酸含有培地で筋管細胞に分化誘導させる工程、及び(3)分化誘導した筋管細胞に電気パルス刺激を与える工程、から成る筋管細胞の作製方法。
2.高アミノ酸含有培地に含まれる各アミノ酸の含量が表1に示された範囲にある、上記1記載の作製方法。
3.電気パルス刺激が10〜50V、0.001〜4Hz、1〜24msパルス幅にて0.5〜120時間与えられる、上記1又は2記載の作製方法。
4.電気パルス刺激が20〜40V、0.1〜1Hz、1〜24msパルス幅にて2〜24時間与えられる、上記3記載の作製方法。
5.少なくとも工程(3)を高酸素分圧状態の培地を用いて行う、上記1〜4のいずれか一項に記載の作製方法。
6.高酸素分圧状態が高酸素濃度ガスを培地に溶解させることにより得られるものである、上記5記載の作製方法。
7.工程(1)が1〜6日間、及び工程(2)が3〜12日間行われる、上記1〜6のいずれか一項に記載の作製方法。
8.弾性基体上で細胞を培養する、上記1〜7のいずれか一項に記載の作製方法。
9.弾性基体が予め細胞接着因子で処理されている、上記8に記載の作製方法。
10.細胞接着因子で予め処理された弾性半透膜から成る底部を有するインサートチャンバー内で細胞を培養し、上下方向に対向して設置された電極によって電気パルス刺激が与えられる、上記1〜9のいずれか一項に記載の作製方法。
11.下部平板電極、ウェル型培養皿、インサートチャンバー、蓋体、及び、上部電極を有する、上下対向電極型電気パルス刺激負荷培養装置。
12.インサートチャンバーの底部が細胞接着因子で予め処理された弾性半透膜から成る、上記11記載の培養装置。
13.上記11又は12記載の培養装置を用いて行うことを特徴とする、上記1〜10のいずれか一項記載の作製方法。
14.上記1〜10のいずれか一項に記載の方法で作製された筋管細胞を用いるインスリン依存的な糖取り込み能の測定方法であって、インスリンを含有する培地で培養することによりインスリン刺激を与えた後、該培地に更に糖を添加して培養し、その後に糖取り込み能を測定することを特徴とする、前記測定方法。
15.インスリンを含有する培地で5〜20分間培養し、該培地に更に10〜50mMのグルコースを添加して10〜50分間培養する、上記14記載の測定方法。
16.測定反応に使用する培地及び反応液が高酸素分圧状態にあることを特徴とする、上記15記載の測定方法。
17.高酸素分圧状態が高酸素濃度ガスを溶液に溶解させることにより得られるものである、上記16記載の測定方法。
18.上記14〜17のいずれか一項に記載の測定方法を利用する筋肉を標的とした薬剤のスクリーニング方法。
That is, the present invention relates to the following aspects.
1. (1) a step of culturing myoblasts, (2) a step of inducing myoblasts to differentiate into myotube cells in a medium containing high amino acids, and (3) a step of applying electrical pulse stimulation to the differentiated myotube cells, A method for producing myotube cells.
2. 2. The production method according to 1 above, wherein the content of each amino acid contained in the high amino acid-containing medium is in the range shown in Table 1.
3. 3. The production method according to 1 or 2 above, wherein the electrical pulse stimulation is applied for 0.5 to 120 hours at 10 to 50 V, 0.001 to 4 Hz, and 1 to 24 ms pulse width.
4). 4. The production method according to 3 above, wherein electrical pulse stimulation is applied at 20 to 40 V, 0.1 to 1 Hz, and 1 to 24 ms pulse width for 2 to 24 hours.
5. The production method according to any one of the above 1 to 4, wherein at least the step (3) is performed using a medium in a high oxygen partial pressure state.
6). 6. The production method according to 5 above, wherein the high oxygen partial pressure state is obtained by dissolving a high oxygen concentration gas in the medium.
7). The production method according to any one of 1 to 6, wherein the step (1) is performed for 1 to 6 days and the step (2) is performed for 3 to 12 days.
8). The production method according to any one of 1 to 7, wherein the cells are cultured on an elastic substrate.
9. 9. The production method according to 8 above, wherein the elastic substrate is previously treated with a cell adhesion factor.
10. Any of 1 to 9 above, wherein the cells are cultured in an insert chamber having a bottom made of an elastic semipermeable membrane pretreated with a cell adhesion factor, and an electric pulse stimulus is applied by electrodes placed facing each other in the vertical direction. The production method according to claim 1.
11. A vertical counter electrode type electric pulse stimulation load culture apparatus having a lower plate electrode, a well-type culture dish, an insert chamber, a lid, and an upper electrode.
12 12. The culture apparatus according to 11 above, wherein the bottom of the insert chamber is composed of an elastic semipermeable membrane pretreated with a cell adhesion factor.
13. The production method according to any one of 1 to 10 above, which is performed using the culture apparatus according to 11 or 12 above.
14 A method for measuring insulin-dependent glucose uptake ability using myotube cells prepared by the method according to any one of 1 to 10 above, wherein insulin stimulation is provided by culturing in a medium containing insulin. And then culturing with further addition of sugar to the medium, and thereafter measuring the sugar uptake ability.
15. 15. The measurement method according to 14 above, wherein the culture is performed in a medium containing insulin for 5 to 20 minutes, 10 to 50 mM glucose is further added to the medium, and the culture is performed for 10 to 50 minutes.
16. 16. The measurement method according to 15 above, wherein the medium and reaction solution used for the measurement reaction are in a high oxygen partial pressure state.
17. 17. The measuring method according to 16 above, wherein the high oxygen partial pressure state is obtained by dissolving a high oxygen concentration gas in a solution.
18. 18. A screening method for drugs targeting muscles using the measurement method according to any one of 14 to 17 above.

本発明方法で作製された筋管細胞は従来の方法に比べて筋構造が発達した肥大した筋管細胞を形成しており、このような筋構造を持つ細胞の割合も増加している。本発明の測定方法を使用することによって、この糖代謝能の亢進を示す指標である、インスリン刺激に反応した糖の取り込み活性が、本発明によって得られた筋管細胞では、従来の細胞に比べ著しく促進されていることが測定できる。従って、本発明方法によって、収縮能および代謝能の両面において、従来と比較して遙かに高度に発達した培養筋細胞を作製し、且つ、該細胞を用いてその代謝能を高感度で評価できる。   Myotube cells produced by the method of the present invention form enlarged myotube cells with a muscular structure developed as compared with the conventional method, and the proportion of cells having such a muscular structure is also increasing. By using the measurement method of the present invention, the myotube cells obtained by the present invention have a glucose uptake activity in response to insulin stimulation, which is an index indicating the enhancement of the ability of glucose metabolism, compared to conventional cells. It can be measured that it is significantly accelerated. Therefore, the method of the present invention makes it possible to produce cultured muscle cells that are much more advanced than conventional methods in terms of both contractility and metabolic capacity, and evaluate the metabolic capacity with high sensitivity using the cells. it can.

更に、本発明に係る上下対向電極型電気パルス刺激負荷培養装置の細胞を含むインサートチェンバー部分の脱着は容易であるため、該培養装置から通常の培養用マルチウェルプレートへと簡便に移動させることができ、自動化も容易である。そのため、本発明による方法を用いて細胞培養を行うことにより、大規模な薬剤の活性評価系へとスムースに移行させることが可能となる。   Furthermore, since it is easy to detach the insert chamber portion containing the cells of the vertical counter electrode type electric pulse stimulation load culture device according to the present invention, it can be easily moved from the culture device to a normal culture multiwell plate. Can be automated. Therefore, by performing cell culture using the method according to the present invention, it is possible to smoothly shift to a large-scale drug activity evaluation system.

本発明の筋管細胞の作製方法において「筋芽細胞」は当業者に公知の任意のものを使用することができる。由来する動物の種類又は組織等に特に制限はないが、ヒトを含む霊長類、マウス及びラット等の哺乳類細胞が好ましく、又、骨格筋、平滑筋及び心筋等に由来するもので良い。   In the method for producing myotube cells of the present invention, any “myoblast” known to those skilled in the art can be used. There are no particular restrictions on the type of animal or tissue derived from it, but primates including humans, mammalian cells such as mice and rats are preferred, and those derived from skeletal muscle, smooth muscle, cardiac muscle and the like may also be used.

更に、「筋芽細胞」として細胞株化された任意の細胞を使用することも出来る。このような細胞株の例として、マウス筋芽細胞株C2C12(ATCC No. CRL1772)、ラット骨格筋由来の筋芽細胞株L6(ATCC No.CRL1458)及びラット心筋芽細胞株H9C2(ATCC
No.CRL1446)などを挙げることが出来る。
Furthermore, any cell established as a “myoblast” can also be used. Examples of such cell lines include mouse myoblast cell line C2C12 (ATCC No. CRL1772), rat skeletal muscle-derived myoblast cell line L6 (ATCC No. CRL1458) and rat cardiomyocyte cell line H9C2 (ATCC).
No. CRL1446).

培養に使用される培地は細胞の種類等に応じて、公知の任意の種類から当業者が適宜選択することが出来る。例えば、ダルベッコ改変イーグル培地(DMEM培地)及び最小必須培地(MEM培地)等を挙げることが出来る。更にこれらの培地には、細胞の分化誘導を阻害しない範囲で、細胞の増殖を促進する等の目的で、各種因子、例えば、ウシ胎児血清(FBS)、アルブミン、トランスフェリン、ホルモン、細胞成長因子、ビタミン等を適宜含有させることが出来る。   The medium used for the culture can be appropriately selected by a person skilled in the art from any known type according to the type of cells. Examples thereof include Dulbecco's modified Eagle medium (DMEM medium) and minimum essential medium (MEM medium). Furthermore, these media contain various factors such as fetal bovine serum (FBS), albumin, transferrin, hormone, cell growth factor, etc. for the purpose of promoting cell proliferation within a range not inhibiting cell differentiation induction. Vitamins and the like can be appropriately contained.

通常、播種細胞数1〜5x10個/ウェル程度、湿度100%、培養温度37℃、培地のpH7.2〜7.4程度で培養を実施するが、その他の培養条件は通常の範囲で当業者が適宜決めることが出来る。 Usually, the culture is performed at 1 to 5 × 10 5 seeded cells / well, 100% humidity, 37 ° C. culture temperature, pH 7.2 to 7.4, and other culture conditions are within the normal range by those skilled in the art. It can be decided as appropriate.

本発明の筋管細胞の作製方法において、第一段階の筋芽細胞を培養する段階は、通常、1〜6日間程度、好ましくは、筋芽細胞が増殖してコンフルエント(培養容器表面全体に密になった状態)になるまで実施する。例えば、筋芽細胞株を1〜6日程度、10〜20%ウシ胎児血清添加DMEM培地にて密になるまで培養する。   In the myotube cell production method of the present invention, the first stage of culturing myoblasts is usually about 1 to 6 days. Preferably, myoblasts proliferate and become confluent (dense over the entire surface of the culture vessel). Until it becomes (). For example, the myoblast cell line is cultured for about 1 to 6 days until it becomes dense in DMEM medium supplemented with 10 to 20% fetal bovine serum.

第ニ工程及び第三工程で使用する培地は高アミノ酸含有培地である。その結果、分化誘導が促進され、電気パルス刺激による収縮活動に伴う培養細胞の疲労を除去することが出来る。高アミノ酸含有培地に含まれる各アミノ酸の含量(mg/l)は、通常の培地に含まれる量の約2〜5倍の必須アミノ酸ならびに、通常の培地に含まれない非必須アミノ酸(L-アラニン、L-アスパラギン、L-アスパラギン酸、L-グルタミン酸、L-プロリン)を添加したものに相当し、代表的な例を以下の表1に示す。   The medium used in the second step and the third step is a high amino acid-containing medium. As a result, differentiation induction is promoted, and fatigue of cultured cells accompanying contractile activity due to electrical pulse stimulation can be eliminated. The content (mg / l) of each amino acid contained in the high amino acid-containing medium is about 2 to 5 times as many essential amino acids as the amount contained in the normal medium, as well as non-essential amino acids (L-alanine not contained in the normal medium). , L-asparagine, L-aspartic acid, L-glutamic acid, L-proline), and typical examples are shown in Table 1 below.

Figure 0004710008
Figure 0004710008

筋芽細胞の分化誘導効果を促進するために、少なくとも第三工程で使用する培地を高酸素分圧状態にすることが好ましい。更に、全ての工程で使用する培地を高酸素分圧状態にすることがより好ましい。かかる高酸素分圧状態は、例えば、使用する前に、培地に高酸素濃度ガス(95%酸素、5%二酸化炭素)を適当時間吹き込むことによって、酸素を十分に溶解させることにより得ることが出来る。或いは、本発明方法を高酸素濃度ガス雰囲気下で実施することによっても培地の高酸素分圧状態を達成することが出来る。又、筋管形成を促進させるための栄養源の補給及び老廃物の除去を目的とした培地交換は適当な間隔(例えば、12〜24時間おき)に実施することが好ましい。 In order to promote the differentiation-inducing effect of myoblasts, it is preferable that the medium used in at least the third step is in a high oxygen partial pressure state. Furthermore, it is more preferable that the medium used in all steps is in a high oxygen partial pressure state. Such a high oxygen partial pressure state can be obtained by, for example, sufficiently dissolving oxygen by blowing a high oxygen concentration gas (95% oxygen, 5% carbon dioxide) into the medium for an appropriate time before use. . Alternatively, a high oxygen partial pressure state of the medium can be achieved also by carrying out the method of the present invention in a high oxygen concentration gas atmosphere. Moreover, it is preferable to perform the culture medium exchange for the purpose of replenishing nutrient sources and removing wastes for promoting myotube formation at appropriate intervals (for example, every 12 to 24 hours).

又、第二工程及び第三工程で使用する培地に添加されるウシ血清濃度は比較的低いことが好ましく、例えば、1〜5%の範囲である。更に、栄養補強の目的で適当量(0.5〜10 g/l)のグルコース等の糖を添加することが出来る。又、筋細胞の分化およびインスリン反応性に大きく影響を与える各種物質、例えば、アスコルビン酸、レチノイン酸、K252a(チロシンキナーゼの活性を修飾する薬剤)、PPAR(peroxisome proliferater-activated receptors)群のアゴニスト・アンタゴニスト等も添加することが出来る。   The bovine serum concentration added to the medium used in the second step and the third step is preferably relatively low, for example, in the range of 1 to 5%. Furthermore, an appropriate amount (0.5 to 10 g / l) of sugar such as glucose can be added for the purpose of nutritional enhancement. In addition, various substances that greatly affect myocyte differentiation and insulin responsiveness, for example, ascorbic acid, retinoic acid, K252a (drug that modifies the activity of tyrosine kinase), PPAR (peroxisome proliferater-activated receptors) Antagonists and the like can also be added.

第二工程は、通常、3〜12日間行われ、筋芽細胞を筋菅細胞に分化誘導させる。第三工程は、分化誘導した筋菅細胞に電気パルス刺激を与える段階であり、かかる電気パルス刺激は、好ましくは、10〜50V、0.001〜4Hz、1〜24msパルス幅にて0.5〜120時間、更に好ましくは、20〜40V、0.1〜1Hz、1〜24msパルス幅にて2〜24時間与えられる。この電気刺激により、細胞の膜電位依存性チャンネルを活性化し、筋細胞のサルコメア構造を発達させる。さらに、同時に収縮活動を促進させてエネルギー消費量を高める。尚、このような電気パルスを発生させる装置自体は当業者に公知である。尚、電気刺激は水平方向又は垂直方向にかけることができるが、電気刺激を垂直方向にかける本発明の上下対向電極型電気パルス刺激負荷培養装置を用いることによって、得られた筋菅細胞をその後のシステム、例えば、薬剤の活性評価系等へと簡便に移行させることが可能となる。   The second step is usually performed for 3 to 12 days to induce myoblasts to differentiate into myocardial cells. The third step is a step of applying an electrical pulse stimulus to the differentiated myoblast, and the electrical pulse stimulus is preferably 10 to 50 V, 0.001 to 4 Hz, 1 to 24 ms with a pulse width of 0.5 to 120 hours, More preferably, it is applied for 2 to 24 hours at 20 to 40 V, 0.1 to 1 Hz, and 1 to 24 ms pulse width. This electrical stimulation activates cell membrane voltage-gated channels and develops the sarcomeric structure of muscle cells. At the same time, the energy consumption is increased by promoting the contraction activity. It should be noted that devices for generating such electric pulses are known to those skilled in the art. The electrical stimulation can be applied in the horizontal direction or the vertical direction, but by using the vertical counter electrode type electric pulse stimulation load culture device of the present invention in which the electrical stimulation is applied in the vertical direction, This system can be easily transferred to, for example, a drug activity evaluation system.

分化誘導の過程で筋細胞の収縮力が増加するために、培養中に自らの収縮活動により細胞が培養面から剥離する可能性がある。そこで、これを防ぐ為に、弾性基体上で細胞を培養することが好ましい。この基体は、筋細胞の増殖に悪影響を与えないようなものであれば当業者に公知の任意の材質、例えば、ヒドロキシエチルメタクリレート(HEMA)、ポリエチレンテレフタレート、及び、マトリゲル等を使用することが出来る。更に、培養後の操作性を考慮して、基体は半透膜のような液体成分が透過できるような形態とすることが好ましい。   Since the contractile force of myocytes increases during the differentiation induction process, the cells may be detached from the culture surface during the culture due to their contractile activity. Therefore, in order to prevent this, it is preferable to culture the cells on an elastic substrate. As this substrate, any material known to those skilled in the art, for example, hydroxyethyl methacrylate (HEMA), polyethylene terephthalate, and matrigel can be used as long as they do not adversely affect the proliferation of muscle cells. . Furthermore, in consideration of operability after culturing, the substrate is preferably in a form that allows liquid components such as a semipermeable membrane to permeate.

更に、筋細胞の分化誘導と細胞接着を促進させるために、コラーゲン、フィブロネクチン、及びエラスチン等の当業者に公知の細胞接着因子(細胞外基質)、徐放性の分化誘導促進因子、薬剤、および栄養素等で基体を予め処理することが好ましい。これは、当業者に公知の任意の手段、例えば、該基体をこのような各物質を含む溶液に浸すことでこれらの物質を基体表面へと予め吸着させる等の手段によって実施することが出来る。尚、この溶液に含まれる上記各物質の割合及び濃度等は、培養細胞の種類、培地の種類、弾性基体の材質等の応じて当業者が適宜選択することが出来、その結果、細胞が接着する基体表面に適度な弾性を持たせることができる。   Furthermore, in order to promote the differentiation induction and cell adhesion of muscle cells, cell adhesion factors (extracellular matrix) known to those skilled in the art, such as collagen, fibronectin, and elastin, sustained-release differentiation induction promoting factors, drugs, and It is preferable to pre-treat the substrate with nutrients or the like. This can be performed by any means known to those skilled in the art, for example, by preliminarily adsorbing these substances onto the surface of the substrate by immersing the substrate in a solution containing such substances. The ratio and concentration of each substance contained in this solution can be appropriately selected by those skilled in the art according to the type of cultured cells, the type of medium, the material of the elastic substrate, etc. Appropriate elasticity can be given to the surface of the substrate.

本発明の筋管細胞の作製方法に使用する培養装置に特に制限は特にないが、好適な構成例として、例えば、下部平板電極、ウェル型培養皿、インサートチャンバー、蓋体、及び、上部電極を有する、本発明の上下対向電極型電気パルス刺激負荷培養装置を挙げることが出来る。ここで、上下電極間に挿入されるインサートチャンバーの底部は細胞接着因子で予め処理された弾性の半透膜のような基体から成ることが好ましい。このような半透膜自体は、例えば、ポリエチレンテレフタレートやヒドロキシエチルメタクリレート(HEMA)等の素材から成っている。本発明装置には、電気パルス発生装置等のその他の任意の構成要素を含むことが出来る。   There are no particular limitations on the culture apparatus used in the myotube production method of the present invention, but examples of suitable configurations include a lower plate electrode, a well-type culture dish, an insert chamber, a lid, and an upper electrode. The vertical counter electrode type electric pulse stimulation load culture apparatus of the present invention can be exemplified. Here, it is preferable that the bottom of the insert chamber inserted between the upper and lower electrodes is made of a substrate such as an elastic semipermeable membrane pretreated with a cell adhesion factor. Such a semipermeable membrane itself is made of a material such as polyethylene terephthalate or hydroxyethyl methacrylate (HEMA). The device of the present invention can include other optional components such as an electric pulse generator.

本発明装置の概略構成を図1に示す。図1の装置では、電気伝導性電極板(1)を底面に設置したウエル型培養皿(2)を用いており、このウエル型培養皿上に筋細胞培養用培地を添加する。その上部のインサートチャンバー(3)内に底部に設置された処理済半透膜(5)上で細胞を培養する。蓋体(4)に設置された上部電極と下部平板電極との間で垂直方向の適当な電気パルス刺激を加える。   A schematic configuration of the apparatus of the present invention is shown in FIG. In the apparatus of FIG. 1, a well-type culture dish (2) having an electrically conductive electrode plate (1) installed on the bottom is used, and a myocyte culture medium is added to the well-type culture dish. Cells are cultured on the treated semipermeable membrane (5) placed at the bottom in the upper insert chamber (3). Appropriate electric pulse stimulation in the vertical direction is applied between the upper electrode and the lower plate electrode placed on the lid (4).

筋細胞の代謝能、特に、糖の取り込み活性は、培養液中の糖の濃度に依存して敏感に変化してしまう、という問題点がある。本発明の測定方法においては、筋管細胞の代謝能の評価を行う際に、従来の反応液(Krebs-Ringer Phosphate Buffer HEPES:KRPH)に適当量(例えば、1〜1000nM程度)のインスリンを含有する培地で適当な時間(例えば、5〜20分間)培養することによりインスリン刺激を与えた後、適当量(例えば、10〜50mM、好ましくは10〜35mM、特に25mM前後)の糖(例えば、グルコース)を添加し、更に一定時間(10〜50分間程度)培養し、その後に測定することにより、上記問題点が解決される。即ち、本発明の測定方法は、基底状態の糖取り込み量が減少し、インスリン依存的な糖取り込みが極めてよく評価できる系であることが確認された。即ち、生体の筋で観察されるインスリン反応性が、本発明の測定方法によって再現できることが示された。更に、代謝反応に必須である酸素を十分に供給するため、測定段階において、既に記載の方法によって富酸素状態にした培地及び反応液を用いることが好ましい。従って、代謝能の評価は、従来の2−デオキシグルコースの取り込み方法(Kanzaki
M and Pessin JE, J Biol Chem, 2001年、第276巻(45号), 42436-42444頁)に上記の点を改変したものを用いる。
There is a problem that the metabolic capacity of muscle cells, particularly the sugar uptake activity, changes sensitively depending on the sugar concentration in the culture medium. In the measurement method of the present invention, an appropriate amount (for example, about 1 to 1000 nM) of insulin is contained in a conventional reaction solution (Krebs-Ringer Phosphate Buffer HEPES: KRPH) when evaluating the metabolic capacity of myotube cells. Insulin stimulation is performed by culturing in a culture medium for an appropriate time (for example, 5 to 20 minutes), and then an appropriate amount (for example, 10 to 50 mM, preferably 10 to 35 mM, particularly about 25 mM) of sugar (for example, glucose) ), Followed by further culturing for a certain period of time (about 10 to 50 minutes), followed by measurement to solve the above problems. That is, it was confirmed that the measurement method of the present invention is a system in which the amount of sugar uptake in the ground state is reduced and insulin-dependent sugar uptake can be evaluated very well. That is, it was shown that the insulin responsiveness observed in living muscles can be reproduced by the measurement method of the present invention. Furthermore, in order to sufficiently supply oxygen essential for metabolic reaction, it is preferable to use a culture medium and a reaction solution that have been enriched by the method described above in the measurement stage. Therefore, the evaluation of metabolic capacity is based on the conventional 2-deoxyglucose uptake method (Kanzaki
M and Pessin JE, J Biol Chem, 2001, Vol. 276 (No. 45), pages 42436-42444) are used in which the above points are modified.

以下、実施例に則して本発明を更に説明するが、これはあくまで本発明の一例であり、本発明の技術的範囲はこれらによって限定されるものではなく、本明細書の記載に基き、当業者が容易に想到し得る任意の変型・修飾法も本発明の範囲である。尚、以下の各実験は図1に記載の上下対向電極型電気パルス刺激負荷培養装置を用いて実施した。尚、以下の作製例等においては、高アミノ酸含有培地として、表1に記載される範囲の最高値のアミノ酸を含有する培地を使用したが、これは、高アミノ酸含有による効果をより明確に示す目的で行ったものであり、これらの値より少量のアミノ酸含量の場合でも、本発明の所定の効果を奏効することができる。   Hereinafter, the present invention will be further described with reference to examples, but this is merely an example of the present invention, and the technical scope of the present invention is not limited thereto, and based on the description of the present specification, Any modification or modification method that can be easily conceived by those skilled in the art is also within the scope of the present invention. In addition, each experiment below was implemented using the upper / lower counter electrode type electric pulse stimulation load culture apparatus shown in FIG. In the following preparation examples and the like, a medium containing the highest amino acid in the range shown in Table 1 was used as the medium containing high amino acid, which shows the effect of high amino acid content more clearly. Even if the amino acid content is smaller than these values, the predetermined effect of the present invention can be obtained.

作製例1:
上記装置のインサートチェンバー内の多孔性の半透膜上にコラーゲン(0.1〜100 μg/ml)、フィブロネクチン(1〜100
μg/ml)、及びエラスチン(1〜100 μg/ml)の細胞外基質と筋細胞の分化を促す薬剤(K252a=100 nM)の混合液を添加し、室温にて数時間放置した。その後、こうして特殊処理したインサートチェンバーから混合液を除去し、ダルベッコ改変リン酸生理食塩緩衝液にて数回洗浄したものに、マウス筋芽細胞株C2C12細胞を1 x 105個/ウェル(4ウェルプレート)となるように播種した。
Production Example 1:
Collagen (0.1-100 μg / ml), fibronectin (1-100) on the porous semipermeable membrane in the insert chamber of the above device
μg / ml) and a mixture of elastin (1-100 μg / ml) extracellular matrix and a drug that promotes myocyte differentiation (K252a = 100 nM) were added and left at room temperature for several hours. Thereafter, the mixed solution was removed from the insert chamber thus specially treated and washed several times with Dulbecco's modified phosphate physiological saline buffer, and then 1 x 10 5 mouse myoblast cell line C2C12 cells / well (4 wells). Plate).

その後、C2C12筋芽細胞がコンフルエントとなるまで3日間ダルベッコ改変イーグル培地+10%牛胎児血清を用いて培養した。その後、ダルベッコ改変イーグル培地+2%牛血清に置換して8日間の培養を行い、筋管細胞へと分化誘導させた。なお、分化誘導培地は、均一な筋管形成を促進し肥大した筋管を形成するために、各アミノ酸(表1に示した範囲の最高値の含量)を添加したものを用い、更に、95% O2 + 5% CO2混合ガスを直接培地に吹き込んで供給することによる高酸素分圧状態にした。また、栄養源の供給ならびに老廃物の除去を目的に培地交換は分化誘導後、24時間おきに行った。その結果、図2に示されるように、高アミノ酸含有培地(表1に記載される範囲の最高値のアミノ酸含量)を使用することによって筋管細胞が著しく肥大していることがわかる。 Thereafter, the cells were cultured for 3 days using Dulbecco's modified Eagle medium + 10% fetal bovine serum until C2C12 myoblasts became confluent. Thereafter, it was replaced with Dulbecco's modified Eagle medium + 2% bovine serum and cultured for 8 days to induce differentiation into myotube cells. The differentiation-inducing medium used was a medium to which each amino acid (the maximum content in the range shown in Table 1) was added in order to promote uniform myotube formation and form an enlarged myotube. A high oxygen partial pressure state was obtained by supplying a% O 2 + 5% CO 2 mixed gas directly into the culture medium. In addition, medium exchange was performed every 24 hours after differentiation induction for the purpose of supplying nutrient sources and removing waste products. As a result, as shown in FIG. 2, it can be seen that myotube cells are significantly enlarged by using a medium containing a high amino acid (the highest amino acid content within the range shown in Table 1).

上記の高アミノ酸含有培地で分化誘導した筋管細胞に、電気パルス発生装置に接続した本発明装置によって電気パルス刺激(40V, 1Hz, 2ms)を18時間負荷し、α−アクチニン抗体を用いた免疫染色を行い、サルコメア構造の発達をコンフォーカル顕微鏡で観察した。従来の方法(通常DMEM +に2%牛血清よる分化誘導、電気パルス刺激なし)で分化誘導させた細胞と比較して、本発明方法によって分化誘導した細胞においては電気パルス刺激によってサルコメア構造が発達していること(図3)、及び、サルコメア構造を持つ細胞の割合が増加していること(図4)が確認され、高度分化筋管細胞が著しく増加していることがわかる。   Immunization using the α-actinin antibody after loading myotube cells induced to differentiate in the above-mentioned medium containing high amino acid with electrical pulse stimulation (40 V, 1 Hz, 2 ms) for 18 hours by the device of the present invention connected to the electrical pulse generator. Staining was performed and the development of sarcomere structure was observed with a confocal microscope. Compared with cells induced to differentiate by conventional methods (normally DMEM + differentiation induction with 2% bovine serum, without electrical pulse stimulation), sarcomere structure developed by electrical pulse stimulation in cells induced to differentiate by the method of the present invention (FIG. 3) and an increase in the proportion of cells having a sarcomere structure (FIG. 4), it can be seen that highly differentiated myotube cells are significantly increased.

作製例2:
次に、種々の条件で電気パルス刺激を行った際のC2C12細胞の糖取り込み量(エネルギー消費量)の変化を調べた。作製例1と同様にコンフルエント状態にしたC2C12筋芽細胞をDMEM + 2%牛血清で8日間培養した後、図5(A)に示した様々な条件で電気パルス刺激を行った。電気パルス刺激終了後、細胞を氷上に静置して代謝反応を停止させ、その後トリチウムで放射性標識した2-デオキシグルコース(0.1mM, 0.5uCi/ml)を4分間細胞に取り込ませ、その取り込み量の総和を液体シンチレーションカウンターを用いて細胞の糖取り込み量(糖代謝能)を測定した。その結果、ある一定の電気パルス刺激条件下で、電気パルス刺激依存的に細胞の糖取り込み量、すなわちエネルギー消費量が増大したことが示された(図5A)。更に、分化誘導培地として高アミノ酸含有培地(表1に記載される範囲の最高値のアミノ酸含量)を使用した場合に、電気パルス刺激を与えた後の2-デオキシグルコース取り込み量に影響を与えることが示された(図5B)。
Production Example 2:
Next, changes in sugar uptake (energy consumption) of C2C12 cells when electrical pulse stimulation was performed under various conditions were examined. After culturing C2C12 myoblasts in a confluent state in the same manner as in Production Example 1 in DMEM + 2% bovine serum for 8 days, electrical pulse stimulation was performed under various conditions shown in FIG. After the electrical pulse stimulation, the cells are left on ice to stop the metabolic reaction, and then 2-deoxyglucose (0.1 mM, 0.5 uCi / ml) radiolabeled with tritium is taken into the cells for 4 minutes, and the amount of uptake The amount of glucose uptake (sugar metabolism ability) of the cells was measured using a liquid scintillation counter. As a result, it was shown that the amount of sugar uptake, that is, the energy consumption amount of the cell increased in an electric pulse stimulus-dependent manner under a certain electric pulse stimulus condition (FIG. 5A). Furthermore, when a medium containing a high amino acid (the highest amino acid content within the range shown in Table 1) is used as the differentiation induction medium, the amount of 2-deoxyglucose uptake after electrical pulse stimulation is affected. Was shown (FIG. 5B).

比較例1:
次に、分化誘導方法に電気パルス刺激のみを組み合わせた場合のインスリン依存的糖取り込みの変化を調べた。作製例に従い、C2C12細胞を4ウェルプレートに播種し、3日間通常培地(DMEM + 10%牛胎児血清)でコンフルエントとなるまで培養し、その後、通常の分化誘導培地(DMEM + 2%牛血清)で引き続き8日間培養を行い、分化誘導を行った。次に、電気パルス刺激(40V, 1Hz, 24ms, 18h)を負荷した後、インスリンで60分間処理し、その後、上記の方法で2-デオキシグルコース取り込み量を測定して細胞の糖取り込み量(糖代謝能)を評価した。その結果、電気パルス刺激はインスリン依存的な糖取り込み量を増加させるが、基底状態の糖取り込み量をも増加させてしまうため、生体では観察できるインスリン依存性の糖代謝亢進能を、既存の測定系で観察することは困難であることが判明した(図6)。
Comparative Example 1:
Next, the change in insulin-dependent sugar uptake when only the electric pulse stimulation was combined with the differentiation induction method was examined. According to the preparation example, C2C12 cells are seeded in a 4-well plate and cultured for 3 days in normal medium (DMEM + 10% fetal bovine serum) until confluent, and then normal differentiation-inducing medium (DMEM + 2% bovine serum) Then, the cells were cultured for 8 days to induce differentiation. Next, after applying electrical pulse stimulation (40V, 1Hz, 24ms, 18h), treatment with insulin for 60 minutes, and then measuring the amount of 2-deoxyglucose uptake by the above method, the amount of sugar uptake (sugar Metabolic ability) was evaluated. As a result, electrical pulse stimulation increases insulin-dependent glucose uptake, but it also increases the amount of glucose uptake in the ground state. It was found difficult to observe with the system (FIG. 6).

比較例2:
比較例1と同様にC2C12細胞を分化誘導した。次に、無血清培地(低グルコース(5 mM)あるいは、高グルコース(25 mM)を含むDMEM)で4時間培養した後、インスリンで5分間処理した。その後、細胞抽出液を調製、ウェスタンブロット解析を行い、インスリンシグナル(AktやErkのリン酸化)を観察した。高グルコースDMEMで4時間前処理することによって、インスリンシグナルが減弱していることが明らかとなった(図7)。
Comparative Example 2:
Similar to Comparative Example 1, C2C12 cells were induced to differentiate. Next, the cells were cultured for 4 hours in a serum-free medium (DMEM containing low glucose (5 mM) or high glucose (25 mM)) and then treated with insulin for 5 minutes. Thereafter, cell extracts were prepared, Western blot analysis was performed, and insulin signals (Akt and Erk phosphorylation) were observed. It was revealed that insulin signal was attenuated by pretreatment with high glucose DMEM for 4 hours (FIG. 7).

測定例1:
作製例1に従って、C2C12筋芽細胞から分化誘導して得られた筋管細胞を4時間無血清培地(DMEM)で培養して血清中のホルモンの影響を除去した後、KRPH(10mM phosphate buffer, pH7.6, 1mM MgSO4, 1mM CaCl2, 136mM NaCl, 4.7mM KCl, 10mM HEPES (pH7.6)に溶解させた終濃度100nMインスリンで15分間刺激し、その後、100nMインスリンと所定濃度のグルコースを含有するKRPHに培地交換し、さらに45分間処理を継続した。処理後、氷上に細胞培養チャンバーを静置することによって代謝反応を停止させ、富酸素状態のKRPHで3回洗浄を行った。筋管細胞の糖取り込み能は、放射性標識した2-デオキシグルコース(0.1mM, 0.5uCi/ml)を細胞に4分間取り込ませ、どの程度の放射線量が細胞に取り込まれたかを測定することで評価した。インスリン処理15分後に適当な濃度(25 mM)のグルコースを添加することによって、基底状態の糖取り込み量が減少し、インスリン依存的な糖取り込みが極めてよく評価できる系になっていることが確認された。即ち、生体の筋で観察されるインスリン反応性が、本発明の測定方法によって再現できることが示された(図8)。
測定比較例1:
Measurement example 1:
According to Preparation Example 1, myotubes obtained by inducing differentiation from C2C12 myoblasts were cultured in serum-free medium (DMEM) for 4 hours to remove the effects of hormones in serum, and then KRPH (10 mM phosphate buffer, Stimulate with a final concentration of 100 nM insulin dissolved in pH 7.6, 1 mM MgSO 4 , 1 mM CaCl 2 , 136 mM NaCl, 4.7 mM KCl, 10 mM HEPES (pH 7.6) for 15 minutes. The medium was changed to KRPH containing, and the treatment was continued for another 45 minutes, after which the metabolic reaction was stopped by allowing the cell culture chamber to stand on ice and washing was performed three times with oxygen-rich KRPH. Glucose uptake capacity of tubule cells was evaluated by measuring how much radiation dose was taken into cells by taking radiolabeled 2-deoxyglucose (0.1 mM, 0.5 uCi / ml) into the cells for 4 minutes. Glucose at appropriate concentration (25 mM) 15 minutes after insulin treatment It was confirmed that the amount of glucose uptake in the basal state was reduced by the addition of, and the insulin-dependent sugar uptake could be evaluated very well. However, it was shown that it can be reproduced by the measurement method of the present invention (FIG. 8).
Measurement comparison example 1:

又、従来の方法(通常DMEM +に2%牛血清よる分化誘導、電気刺激なし、測定はグルコース無添加のKRPH中で行う)で得られた培養筋細胞のインスリン依存的糖取り込みと本発明方法(アミノ酸増強富酸素化DMEM + 2%牛血清による分化誘導、電気刺激あり(40V, 1Hz, 2ms, 18h)、測定はインスリン処理15分後に25 mMグルコースを加えたKRPH中で行う)で得られた筋管細胞におけるインスリン依存的糖取り込みを比較すると、従来の方法に比べて本発明の作製方法で得られた筋管細胞はインスリンに反応して糖取り込みが顕著に増えていることが示され、これを用いた本発明の測定方法によって、該筋管細胞の高いインスリン依存的糖取り込み能を測定すること可能であることが確認された(図9)。   In addition, insulin-dependent sugar uptake of cultured muscle cells obtained by the conventional method (usually differentiation induction with 2% bovine serum in DMEM +, no electrical stimulation, measurement is performed in KRPH without glucose) and the method of the present invention (Induction of differentiation with amino acid-enriched oxygen enriched DMEM + 2% bovine serum, with electrical stimulation (40V, 1Hz, 2ms, 18h), measurement is performed in KRPH with 25 mM glucose added 15 minutes after insulin treatment) Comparison of insulin-dependent sugar uptake in myotubes showed that myotubes obtained by the production method of the present invention had a marked increase in sugar uptake in response to insulin compared to conventional methods. Thus, it was confirmed that the high insulin-dependent sugar uptake ability of the myotube cells can be measured by the measurement method of the present invention using this (FIG. 9).

尚、上記測定例及び測定比較例において、培養液ならびに反応液は、全て酸素ボンベ(95%O2 + 5%CO2)から2時間2時間酸素を直接溶解させたものを用いた。 In the above measurement examples and measurement comparison examples, the culture solution and the reaction solution were all prepared by directly dissolving oxygen from an oxygen cylinder (95% O 2 + 5% CO 2 ) for 2 hours and 2 hours.

本発明方法により、培養系において、高い代謝能やインスリン反応性を有する優れた培養筋細胞、即ち、生体により近似な高度発達型筋細胞を作製することが可能になった。本発明の測定方法を利用することにより、筋肉を標的とした様々な薬剤(糖尿病治療薬、インスリン抵抗性改善薬、糖の取り込み亢進薬、代謝能改善薬、分化誘導促進薬、収縮増強薬など)のスクリーニングをハイスループット化することが可能になり、該スクリーニングが非常に簡便になる。このようなスクリーニング方法は当業者に公知の任意の方法で行うことが出来る。例えば、試験対象となる薬剤の存在下または非存在下で本発明の測定方法を実施し、得られるインスリン依存的糖取り込み量を比較すること等により行うことが出来る。 The method of the present invention has made it possible to produce excellent cultured muscle cells having high metabolic ability and insulin reactivity, that is, highly developed muscle cells that are more approximate to the living body in the culture system. By using the measurement method of the present invention, various drugs targeting muscles (diabetes therapeutic drugs, insulin resistance improving drugs, sugar uptake enhancing drugs, metabolic capacity improving drugs, differentiation induction promoting drugs, contraction enhancing drugs, etc. ) Can be increased in throughput, and the screening becomes very simple. Such a screening method can be performed by any method known to those skilled in the art. For example, the measurement method of the present invention can be carried out in the presence or absence of the drug to be tested, and the obtained insulin-dependent sugar uptake amount can be compared.

更に、本発明方法において、電気パルス刺激と培養条件を適切に調節することにより、培養筋細胞の分化度と発達度をコントロールすることが可能である。そのため、移植医療に適した分化度・発達度(収縮力や収縮パターン、代謝能)の培養筋細胞を任意に作製することが可能である。   Furthermore, in the method of the present invention, the degree of differentiation and development of cultured muscle cells can be controlled by appropriately adjusting the electrical pulse stimulation and the culture conditions. Therefore, it is possible to arbitrarily produce cultured myocytes having a degree of differentiation / development suitable for transplantation (contraction force, contraction pattern, metabolic ability).

又、作製された培養筋細胞の収縮活動は人為的にコントロールすることができるため、生体の筋肉の運動活動を模倣した状態を培養系において作り出すことが可能になった。本発明を利用することにより、生体における運動(筋肉の収縮伸展活動)刺激がいかにしてインスリン抵抗性を改善しているのか等の培養細胞の利点を生かした研究(例えば、分子生物学、細胞生物学、生化学、遺伝子工学的手法を用いた研究)が可能になる。   Moreover, since the contraction activity of the prepared cultured muscle cells can be artificially controlled, it has become possible to create a state in the culture system that mimics the muscular motor activity of a living body. By utilizing the present invention, research utilizing the advantages of cultured cells such as how the stimulation of muscle movement (muscle contraction / extension activity) improves insulin resistance (for example, molecular biology, cell Biology, biochemistry, research using genetic engineering techniques).

本発明の実施の形態による細胞培養電気刺激装置の概略構成である。1 is a schematic configuration of a cell culture electrical stimulation device according to an embodiment of the present invention. 通常の分化誘導培地(DMEM + 2%牛血清)で得られた培養筋細胞と本発明方法で得られた筋細胞の比較を示す顕微鏡写真(x20)である。It is a microscope picture (x20) which shows the comparison of the cultured myocyte obtained by the normal differentiation-inducing medium (DMEM + 2% bovine serum) and the myocyte obtained by the method of the present invention. 従来の方法で得られた培養筋細胞と本発明方法で得られた筋細胞のα−アクチニン分子を染色してコンフォーカル顕微鏡で撮影した写真(x60)である。It is the photograph (x60) which dye | stained the alpha-actinin molecule | numerator of the cultured myocyte obtained by the conventional method, and the myocyte obtained by the method of this invention, and image | photographed with the confocal microscope. 従来の方法で得られた培養筋細胞と本発明方法で得られた筋細胞における横紋構造を持つ筋細胞の割合を示すグラフである。It is a graph which shows the ratio of the myocyte which has a striated structure in the cultured myocyte obtained by the conventional method, and the myocyte obtained by the method of this invention. ある一定の電気パルス刺激条件下で、電気パルス刺激依存的に細胞の糖取り込み量、すなわちエネルギー消費量の増大したことを示すグラフ(A)である。また、分化誘導培地として高アミノ酸含有培地(表1に記載される範囲の最高値のアミノ酸含量)を使用した場合、さらにそのエネルギー消費量を増大させることができることも明らかとなった(B)。It is a graph (A) which shows that the sugar uptake | capture amount of the cell, ie, the energy consumption amount, increased depending on the electric pulse stimulation under certain electric pulse stimulation conditions. It was also revealed that when a high amino acid-containing medium (the highest amino acid content in the range described in Table 1) is used as the differentiation induction medium, the energy consumption can be further increased (B). 分化誘導方法に電気パルス刺激のみを組み合わせた場合のインスリン依存的糖取り込みの変化を示すグラフである。It is a graph which shows the change of an insulin dependent sugar uptake at the time of combining only an electric pulse irritation | stimulation with the differentiation induction method. 高グルコース処理によるインスリン初期シグナル(AktやErkのリン酸化)が抑制されることを示すウェスタンブロット解析の電気泳動の写真である。It is the photograph of the electrophoresis of the Western blot analysis which shows that the insulin early signal (Akt and Erk phosphorylation) by high glucose treatment is suppressed. 本発明による方法で分化誘導を行ったC2C12筋管細胞について、アッセイ中に存在するグルコース濃度を変更した際の基底状態、ならびにインスリン依存的な糖取り込み量の変化を示すグラフである。It is a graph which shows the change of the basal state at the time of changing the glucose concentration which exists in an assay about the C2C12 myotube cell which induced differentiation by the method by this invention, and an insulin-dependent glucose uptake amount. 従来の方法で得られた培養筋細胞と本発明方法で得られた筋細胞におけるインスリン依存的糖取り込みの比較を示すグラフである。It is a graph which shows the comparison of the insulin-dependent sugar uptake in the cultured myocytes obtained by the conventional method and the myocytes obtained by the method of the present invention.

符号の説明Explanation of symbols

(1)下部平板電極
(2)ウェル型培養皿
(3)インサートチャンバー
(4)蓋体
(5)特殊処理済み半透膜
(6)上部電極
(1) Lower plate electrode (2) Well type culture dish (3) Insert chamber (4) Lid (5) Specially processed semipermeable membrane (6) Upper electrode

Claims (17)

(1)筋芽細胞を培養する工程、(2)筋芽細胞を高アミノ酸含有培地で筋管細胞に分化誘導させる工程、及び(3)分化誘導した筋管細胞に電気パルス刺激を与える工程、から成る筋管細胞の作製方法であって、少なくとも工程(3)を高酸素分圧状態の培地を用いて行うことを特徴とする前記作製方法。 (1) a step of culturing myoblasts, (2) a step of inducing myoblasts to differentiate into myotube cells in a medium containing high amino acids, and (3) a step of applying electrical pulse stimulation to the differentiated myotube cells, A method for producing a myotube cell comprising the step of performing at least step (3) using a medium in a high oxygen partial pressure state. 高アミノ酸含有培地に含まれる各アミノ酸の含量が表1に示された範囲にある、請求項1記載の作製方法。 The production method according to claim 1, wherein the content of each amino acid contained in the high amino acid-containing medium is in the range shown in Table 1. 電気パルス刺激が10〜50V、0.001〜4Hz、1〜24msパルス幅にて0.5〜120時間与えられる、請求項1又は2記載の作製方法。 The production method according to claim 1 or 2, wherein electrical pulse stimulation is applied at 10 to 50 V, 0.001 to 4 Hz, and 1 to 24 ms pulse width for 0.5 to 120 hours. 電気パルス刺激が20〜40V、0.1〜1Hz、1〜24msパルス幅にて2〜24時間与えられる、請求項3記載の作製方法。 The production method according to claim 3, wherein the electric pulse stimulation is applied at 20 to 40 V, 0.1 to 1 Hz, and 1 to 24 ms pulse width for 2 to 24 hours. 高酸素分圧状態が高酸素濃度ガスを培地に溶解させることにより得られるものである、請求項1〜4のいずれか一項に記載の作製方法。 The production method according to any one of claims 1 to 4, wherein the high oxygen partial pressure state is obtained by dissolving a high oxygen concentration gas in a culture medium. 工程(1)が1〜6日間、及び工程(2)が3〜12日間行われる、請求項1〜5のいずれか一項に記載の作製方法。 The production method according to any one of claims 1 to 5, wherein the step (1) is performed for 1 to 6 days, and the step (2) is performed for 3 to 12 days. 弾性基体上で細胞を培養する、請求項1〜6のいずれか一項に記載の作製方法。 The production method according to claim 1, wherein the cells are cultured on an elastic substrate. 弾性基体が予め細胞接着因子で処理されている、請求項7に記載の作製方法。 The production method according to claim 7, wherein the elastic substrate is previously treated with a cell adhesion factor. 細胞接着因子で予め処理された弾性半透膜から成る底部を有するインサートチャンバー内で細胞を培養し、上下方向に対向して設置された電極によって電気パルス刺激が与えられる、請求項1〜8のいずれか一項に記載の作製方法。 The cells are cultured in an insert chamber having a bottom made of an elastic semipermeable membrane pretreated with a cell adhesion factor, and electrical pulse stimulation is applied by electrodes placed opposite to each other in the vertical direction. The manufacturing method as described in any one of Claims. 下部平板電極、ウェル型培養皿、インサートチャンバー、蓋体、及び、上部電極を有する、上下対向電極型電気パルス刺激負荷培養装置を用いて行うことを特徴とする、請求項1〜のいずれか一項に記載の作製方法。 The method according to any one of claims 1 to 9 , which is carried out using a vertical counter electrode type electric pulse stimulation load culture apparatus having a lower plate electrode, a well-type culture dish, an insert chamber, a lid, and an upper electrode. The manufacturing method according to one item. インサートチャンバーの底部が細胞接着因子で予め処理された弾性半透膜から成る、請求項10記載の作製方法。 The manufacturing method according to claim 10, wherein the bottom of the insert chamber is made of an elastic semipermeable membrane pretreated with a cell adhesion factor. (1)筋芽細胞を培養する工程、(2)筋芽細胞を高アミノ酸含有培地で筋管細胞に分化誘導させる工程、及び(3)分化誘導した筋管細胞に電気パルス刺激を与える工程、から成る筋管細胞の作製方法で作製された筋管細胞を用いるインスリン依存的な糖取り込み能の測定方法であって、インスリンを含有する培地で培養することによりインスリン刺激を与えた後、該培地に更に糖を添加して培養し、その後に糖取り込み能を測定することを特徴とする、前記測定方法。 (1) a step of culturing myoblasts, (2) a step of inducing myoblasts to differentiate into myotube cells in a medium containing high amino acids, and (3) a step of applying electrical pulse stimulation to the differentiated myotube cells, A method for measuring insulin-dependent sugar uptake ability using myotube cells produced by the method for producing myotube cells comprising the following: And further culturing with addition of sugar, and then measuring the sugar uptake ability. 請求項1ないし11のいずれか一項に記載の方法で作製された筋管細胞を用いる、請求項12記載のインスリン依存的な糖取り込み能の測定方法。 The method for measuring insulin-dependent glucose uptake ability according to claim 12, wherein the myotube cells produced by the method according to any one of claims 1 to 11 are used. インスリンを含有する培地で5〜20分間培養し、該培地に更に10〜50mMのグルコースを添加して10〜50分間培養する、請求項12又は13記載の測定方法。 The measurement method according to claim 12 or 13, wherein the culture is performed in a medium containing insulin for 5 to 20 minutes, 10 to 50 mM glucose is further added to the medium, and the culture is performed for 10 to 50 minutes. 測定反応に使用する培地及び反応液が高酸素分圧状態にあることを特徴とする、請求項14記載の測定方法。 The measurement method according to claim 14, wherein the medium and the reaction solution used for the measurement reaction are in a high oxygen partial pressure state. 高酸素分圧状態が高酸素濃度ガスを溶液に溶解させることにより得られるものである、請求項15記載の測定方法。 The measurement method according to claim 15, wherein the high oxygen partial pressure state is obtained by dissolving a high oxygen concentration gas in a solution. 請求項12〜16のいずれか一項に記載の測定方法を利用する筋肉を標的とした薬剤のスクリーニング方法。
The screening method of the chemical | medical agent which targeted the muscle using the measuring method as described in any one of Claims 12-16.
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JP2005027501A (en) * 2003-07-07 2005-02-03 Rui Yuge Method for producing automatic contractile muscle cell

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* Cited by examiner, † Cited by third party
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JP2005027501A (en) * 2003-07-07 2005-02-03 Rui Yuge Method for producing automatic contractile muscle cell

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