JP2002255821A - Medicine for treating cancer resistant to anticancer medicine - Google Patents
Medicine for treating cancer resistant to anticancer medicineInfo
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- JP2002255821A JP2002255821A JP2001061123A JP2001061123A JP2002255821A JP 2002255821 A JP2002255821 A JP 2002255821A JP 2001061123 A JP2001061123 A JP 2001061123A JP 2001061123 A JP2001061123 A JP 2001061123A JP 2002255821 A JP2002255821 A JP 2002255821A
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- cpt
- cells
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- resistant
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- Nitrogen Condensed Heterocyclic Rings (AREA)
Abstract
Description
【0001】[0001]
【発明の属する技術分野】本発明は、各種抗癌剤に対し
て耐性を示す癌細胞に対して強い抗腫瘍活性を有するカ
ンプトテシン誘導体に関し、これらを用いた治療剤に関
する。TECHNICAL FIELD The present invention relates to a camptothecin derivative having a strong antitumor activity against cancer cells exhibiting resistance to various anticancer drugs, and relates to a therapeutic agent using the same.
【0002】[0002]
【従来の技術】カンプトテシン(camptothecin、以下C
PTと略記する)は、中国原産の喜樹(Camptotheca ac
uminata)の葉や樹皮などに含有されるアルカロイドで
あり、またCPTの半合成誘導体である7−エチル−1
0−ピペリジノピペリジノカルボニルオキシカンプトテ
シン(以下CPT−11と略記する、特公平3−407
7号公報参照)はCPTの高い抗腫瘍活性を維持し、か
つ毒性が軽減された化合物として特に重要な物質であ
る。このCPT−11は、生体内では代謝されて、同様
にCPTの半合成誘導体である7−エチル−10−ヒド
ロキシカンプトテシン(以下SN−38と略記する、特
公昭62−47193号公報参照)となり、活性が現れ
るとされている。2. Description of the Related Art Camptothecin (hereinafter referred to as C)
PT (abbreviated as PT) is a Chinese native tree (Camptotheca ac)
uminata) 7-ethyl-1 which is an alkaloid contained in leaves, bark, etc., and a semi-synthetic derivative of CPT.
0-piperidinopiperidinocarbonyloxycamptothecin (hereinafter abbreviated as CPT-11;
No. 7) is a particularly important substance as a compound that maintains the high antitumor activity of CPT and has reduced toxicity. This CPT-11 is metabolized in the living body into 7-ethyl-10-hydroxycamptothecin, which is also a semi-synthetic derivative of CPT (hereinafter, abbreviated as SN-38; see JP-B-62-47193). It is said that activity appears.
【0003】即ち、CPT−11はSN−38のプロド
ラッグ(pro-drug)ということができる。このCPT−
11がSN−38に代謝されて抗腫瘍活性を示す作用機
構については、幾つかの文献に詳細に報告されている
(Kanedaら,Cancer Res., 50,1715(1990), Nagataら,
J. Aichi Med. Univ. Assoc., 15, 683(1987)、Tricoli
ら, Exp. Cell. Res., 158, 1(1985)、Nagataら, Cance
r Treatment Reports,71, 341(1987)参照)。CPT、
SN−38、CPT−11などで代表される、CPT誘
導体群は、いずれも、強い抗腫瘍活性を有することが知
られており、なかでもCPT−11は現在臨床において
抗腫瘍剤として広く使用されている。[0003] That is, CPT-11 can be said to be a pro-drug of SN-38. This CPT-
The mechanism by which 11 is metabolized to SN-38 and exhibits antitumor activity has been reported in detail in several documents (Kaneda et al., Cancer Res., 50, 1715 (1990), Nagata et al.,
J. Aichi Med. Univ. Assoc., 15, 683 (1987), Tricoli
Res., 158, 1 (1985); Nagata et al., Cance.
r Treatment Reports, 71, 341 (1987)). CPT,
All of the CPT derivatives represented by SN-38, CPT-11 and the like are known to have strong antitumor activity. Among them, CPT-11 is currently widely used in clinical practice as an antitumor agent. ing.
【0004】一方、癌の化学療法における課題として、
化学療法剤に対しての癌細胞の耐性獲得があり、最近C
PT−11に対する耐性獲得腫瘍細胞も発見された。こ
のことは、CPT−11による癌の化学療法に制限を与
えるものである。癌細胞の耐性獲得の主な機構として、
CPT−11の標的分子であるトポイソメラーゼI(to
po I )のポイントミューテーション1)、topo I 発現量
の減少、breast cancer resistant protein (BCR
P) 2)、または Multi resistance protein 2 (MRP2) 3)
の過剰発現による細胞からの分子排出の増加があげられ
る。従って、BCRP や MRP2 の基質とならないで、耐性
を獲得した癌細胞に対しても有効なCPT誘導体を得る
ことは薬剤耐性の克服の観点から極めて重要である。On the other hand, as a problem in cancer chemotherapy,
Cancer cells have acquired resistance to chemotherapeutic agents.
Tumor cells with acquired resistance to PT-11 were also found. This limits the chemotherapy of cancer with CPT-11. As the main mechanism of cancer cell resistance acquisition,
Topoisomerase I, a target molecule of CPT-11 (to
po I) point mutation 1) , decreased expression of topo I, breast cancer resistant protein (BCR
P) 2) , or Multi resistance protein 2 (MRP2) 3)
Increased expression of molecules from cells due to overexpression of. Therefore, obtaining an effective CPT derivative even for cancer cells that have acquired resistance without being a substrate for BCRP or MRP2 is extremely important from the viewpoint of overcoming drug resistance.
【0005】[0005]
【発明が解決しようとする課題】従って、本発明の目的
は、抗腫瘍活性が強く、かつ BCRPおよび MRP2 過剰発
現によるCPT−11耐性株に対しても殺細胞作用を示
すCPT誘導体を提供することにある。Accordingly, an object of the present invention is to provide a CPT derivative having a strong antitumor activity and exhibiting a cell killing effect even on a CPT-11 resistant strain due to overexpression of BCRP and MRP2. It is in.
【0006】[0006]
【課題を解決するための手段】そこで、本発明者らは、
上記課題を解決すべく鋭意研究を重ねる中で、各種CP
T誘導体について検討した結果、式(I)で表されるC
PT誘導体が抗癌剤耐性癌に対して優れた抗腫瘍効果を
有することを見出し、本発明を完成した。すなわち、本
発明は、式(1)Means for Solving the Problems Accordingly, the present inventors have:
While conducting intensive research to solve the above problems, various CP
As a result of studying the T derivative, it was found that C represented by the formula (I)
The present inventors have found that a PT derivative has an excellent antitumor effect against an anticancer drug-resistant cancer, and have completed the present invention. That is, the present invention relates to formula (1)
【化2】 (式中、Xは水素、ハロゲン原子、アミノ基、低級アル
キル基、低級アルコキシル基または水酸基であり、Yは
水素、ハロゲン原子または水酸基であり、Xが水酸基でY
が水素のものを除く)で表されるカンプトテシン誘導体
を有効成分とする、抗癌剤耐性癌に対する治療剤に関す
る。本発明において、式(I)中の上記低級アルキル基
は、炭素原子1〜5個を有するアルキル基、特に炭素原
子1〜3個を有するアルキル基を意味し、上記低級アル
コキシル基は、炭素原子1〜5個を有するアルコキシル
基、特に炭素原子1〜3個を有するアルコキシル基を意
味する。また、本発明は、抗癌剤耐性癌が塩酸イリノテ
カン(CPT−11)に対する耐性癌である、前記治療
剤に関する。Embedded image (Wherein X is hydrogen, a halogen atom, an amino group, a lower alkyl group, a lower alkoxyl group or a hydroxyl group, Y is hydrogen, a halogen atom or a hydroxyl group, X is a hydroxyl group and Y
A camptothecin derivative represented by the formula (1) except for hydrogen) as an active ingredient. In the present invention, the lower alkyl group in the formula (I) means an alkyl group having 1 to 5 carbon atoms, particularly an alkyl group having 1 to 3 carbon atoms, and the lower alkoxyl group is a carbon atom An alkoxyl group having 1 to 5 carbon atoms, especially an alkoxyl group having 1 to 3 carbon atoms, is meant. The present invention also relates to the therapeutic agent, wherein the anticancer drug-resistant cancer is a cancer resistant to irinotecan hydrochloride (CPT-11).
【0007】本発明に係る抗癌剤耐性癌に対する治療剤
としてのCPT誘導体は、後述するように、in vitroお
よびin vivoの試験系で優れた抗腫瘍効果を有している
ことが確認され、また、CPT−11やSN−38に比
べて、BCRPやMRP2の基質になり難い特徴を有しているこ
とが確認され、抗癌剤に耐性を獲得した耐性癌に対して
有効である。[0007] The CPT derivative as a therapeutic agent for anticancer drug-resistant cancer according to the present invention has been confirmed to have excellent antitumor effects in in vitro and in vivo test systems, as described below. Compared to CPT-11 and SN-38, it has been confirmed that it has a characteristic of being less likely to be a substrate for BCRP or MRP2, and is effective against resistant cancers that have acquired resistance to anticancer drugs.
【0008】[0008]
【発明の実施の形態】以下、本発明の実施の形態につい
て説明する。本発明に係る抗癌剤耐性癌に対する治療剤
は、CPTのB環7位にエチル基を有し、A環10位お
よび/または11位に各種置換基を有するCPT誘導体
を有効成分とするものである。これらの誘導体は、公知
の全合成による方法(特開平1−186892参照)ま
たはA環に置換基を有する天然のCPT誘導体から半合
成による方法により製造することができる。例えば、公
知化合物である(S)−4−エチル−7,8−ジヒドロ−4−ヒ
ドロキシ−1H−ピラノ[3,4−f]インドリジン−3,6,10(4
H)−トリオンと4位がYで置換され5位がXで置換され
た2-アミノ-4-ヒドロキシプロピオフェノンとを反応(P&
Uルート(Henegar, K. E.; Ashford, S. W.; Baughman,
T. A.; Sih, J. C.; Gu, R. L. J. Org. Chem. 1997,
62, 6588-6597.)により合成)させて得ることができ
る。Embodiments of the present invention will be described below. The therapeutic agent for anticancer drug-resistant cancer according to the present invention comprises a CPT derivative having an ethyl group at the 7-position of B ring and various substituents at the 10- and / or 11-position of the A ring of CPT as an active ingredient. . These derivatives can be produced by a known total synthesis method (see JP-A-1-186892) or a semi-synthesis method from a natural CPT derivative having a substituent on the A ring. For example, a known compound (S) -4-ethyl-7,8-dihydro-4-hydroxy-1H-pyrano [3,4-f] indolizine-3,6,10 (4
Reaction of (H) -trione with 2-amino-4-hydroxypropiophenone substituted at position 4 by Y and position 5 by X (P &
U route (Henegar, KE; Ashford, SW; Baughman,
TA; Sih, JC; Gu, RLJ Org. Chem. 1997,
62, 6588-6597.).
【0009】本発明に係る治療剤の投与方法は、適宜選
択されるが、例えば、皮下投与、静脈投与、筋肉注射で
投与することができる。また常法により各種製剤に加工
して用いることができ、例えば、薬学上許容される安定
剤、浸透圧調整剤、pH調整剤等の助剤とともに注射剤
等に製剤化することができる。また、各薬剤を使用時に
混合して使用する形態をとってもよい。本発明に係る治
療剤において用いられるCPT誘導体の投与量は、腫瘍
の種類、症状により適宜選択すればよいが、一日当たり
0.1〜100mg/体重kgが好ましく、特に0.5〜20mg
/体重kgが好ましい。また、他の化学療法剤との併用
も有効である。The method of administration of the therapeutic agent according to the present invention is appropriately selected. For example, it can be administered subcutaneously, intravenously or intramuscularly. In addition, it can be processed into various preparations by a conventional method and used, for example, can be formulated into an injection or the like together with pharmaceutically acceptable auxiliaries such as a stabilizer, an osmotic pressure adjusting agent and a pH adjusting agent. In addition, a form may be used in which each drug is mixed and used at the time of use. The dose of the CPT derivative used in the therapeutic agent according to the present invention may be appropriately selected depending on the type and condition of the tumor.
0.1-100 mg / kg of body weight is preferred, especially 0.5-20 mg
/ Kg of body weight is preferred. Also, combination with other chemotherapeutic agents is effective.
【0010】[0010]
【実施例】次に、実施例により本発明をさらに詳細に説
明するが、本発明はこれらに限定されるものではない。Next, the present invention will be described in more detail with reference to examples, but the present invention is not limited to these examples.
【0011】1.in vivo による抗腫瘍効果の試験 7週令の CDF1 マウス (雌) を用いた。一群6または1
0匹とし、マウスの腹腔内に L1210 細胞 (105 cells)
を移植した。検体は腫瘍の移植後、1、5、9日目に腹
腔内投与し、その後のマウスの生存日数を調べた。生存
日数は以下の式より延命率 (T/C) として示した。 T/C = 投与群の平均生存日数/コントロール群の平均生
存日数 × 100 40日間マウスの生死を観察した。検体は生理食塩水、
または注射用蒸留水に溶解、または懸濁して投与した。
コントロール群には生理食塩水、または注射用蒸留水の
みを投与した。試験に供したCPT誘導体の構造式を表
1に、また抗腫瘍効果試験の結果を表2、表3に示す。1. Test of antitumor effect in vivo A 7-week-old CDF1 mouse (female) was used. 6 or 1 group
0 mice and L1210 cells (10 5 cells) intraperitoneally
Was transplanted. Specimens were intraperitoneally administered on days 1, 5, and 9 after tumor implantation, and the number of days after which the mice survived was examined. The survival days were expressed as the survival rate (T / C) according to the following formula. T / C = average surviving days of the administration group / average surviving days of the control group × 100 The survival of the mice was observed for 40 days. The specimen is saline,
Alternatively, it was dissolved or suspended in distilled water for injection and administered.
The control group received only physiological saline or distilled water for injection. The structural formula of the CPT derivative subjected to the test is shown in Table 1.
1 and Table 2 and Table 3 show the results of the antitumor effect test.
【0012】[0012]
【表1】 [Table 1]
【0013】[0013]
【表2】 [Table 2]
【0014】[0014]
【表3】 [Table 3]
【0015】SN-444 を除き、全てのCPT誘導体は所
定の投与量において 100% 以上の T/C を示した。従っ
て、SN-444 を除き、本発明に用いられるCPT誘導体
は in vivo レベルで抗腫瘍活性を示し、これらは抗癌
剤として利用することができる。SN-444 は以下に示し
た in vitro 系の試験で L1210 を含む腫瘍細胞に対し
て殺細胞作用を示したことから、投与経路の変更など工
夫することにより的確に誘導体を腫瘍組織に送達するこ
とで、これも抗癌剤として利用することができる。With the exception of SN-444, all CPT derivatives showed a T / C of more than 100% at a given dose. Therefore, except for SN-444, the CPT derivatives used in the present invention show antitumor activity at an in vivo level, and they can be used as anticancer agents. Since SN-444 showed cytocidal activity against tumor cells containing L1210 in the following in vitro test, the derivative can be accurately delivered to tumor tissues by modifying the administration route. Thus, this can also be used as an anticancer agent.
【0016】2.In vitroによる殺細胞効果の試験 (1)使用細胞および細胞培養法 ヒト鼻咽腔癌由来の KB (大日本製薬 (株)) は10% 牛血
清 (Gibco) を添加したE-MEM (日水製薬) にて、また
ヒト白血病細胞 L1210 (大日本製薬 (株)) は10% 牛胎
児血清を添加した RPMI1640 medium (日水製薬) に
て、37℃、5% 炭酸ガス条件下で培養した。ヒト白血病
細胞; L1210、ヒト小細胞肺癌細胞; PC-6、同細胞の
SN-38耐性株; PC-6/SN2-5H(長崎大学医学部より入
手)、およびヒト肝臓癌細胞; HepG2 を使用した。PC-
6 は硫酸カナマイシン (明治製菓、50mg/l)、および 10
% 牛胎児血清 (Gibco) を含む RPMI1640 (SIGMA) 培地
中、37℃、5% 炭酸ガス条件下で培養した。PC-6/SN2-5H
はさらにSN-38 を添加した (終濃度25 nM) 上記培地中
で、37℃、5% 炭酸ガス条件下で培養した。HepG2は硫酸
カナマイシン (50mg/l)、および 10% 牛胎児血清を含む
D-MEM (SIGMA) 培地中、37℃、5% 炭酸ガス条件下で培
養した。2. Test of cell killing effect in vitro (1) Cells used and cell culture method KB (Dainippon Pharmaceutical Co., Ltd.) derived from human nasopharyngeal carcinoma was E-MEM (Nissui) supplemented with 10% bovine serum (Gibco). And L1210 human leukemia cells (Dainippon Pharmaceutical Co., Ltd.) were cultured in RPMI1640 medium (Nissui Pharmaceutical) supplemented with 10% fetal calf serum under conditions of 37 ° C. and 5% carbon dioxide. Human leukemia cells; L1210, human small cell lung cancer cells; PC-6,
An SN-38 resistant strain; PC-6 / SN2-5H (obtained from Nagasaki University School of Medicine), and a human liver cancer cell; HepG2 were used. PC-
6 is kanamycin sulfate (Meiji Seika, 50 mg / l), and 10
The cells were cultured in RPMI1640 (SIGMA) medium containing 5% fetal bovine serum (Gibco) at 37 ° C. under 5% carbon dioxide. PC-6 / SN2-5H
Was further cultured in the above medium supplemented with SN-38 (final concentration 25 nM) under the conditions of 37 ° C. and 5% carbon dioxide. HepG2 contains kanamycin sulfate (50mg / l) and 10% fetal calf serum
The cells were cultured in a D-MEM (SIGMA) medium at 37 ° C. under 5% carbon dioxide.
【0017】(2)細胞増殖阻止活性測定法 KBを用いた系ではDay -1に対数増殖期の細胞を2 x 104
cells/mlに培養液で希釈し、3 mlを60 mmプラスチック
ディッシュに植え込んだ (6 x 104 cells/dish)。これ
を一晩培養後、Day 0に適当濃度の各薬剤を含む培養液
に交換し、3日間培養を続けた。Day 3に細胞をPBS (日
水製薬)にて洗浄後、ディッシュより 0.25% トリプシン
溶液 (Gibco) 0.5 ml を用いて剥離し、その全量を生理
食塩水にて10 mlに希釈した。L1210 を用いた系では Da
y 0に対数増殖期の細胞を2 x 104 cells/mlに培養液で
希釈し、ウェルあたり0.5 mlを24穴プラスチックプレー
トに植え込んだ (104 cells/well)。これを3時間培養
後,2倍濃度の各薬剤を含む培養液を0.5 ml/wellで加
え、3日間培養を続けた。Day 3にウェル全量を生理食塩
水にて10 mlに希釈した。生理食塩水に希釈した細胞浮
遊液は、Coulter Counter (Type ZM, Coulter Electron
ics) で 0.5ml あたりの細胞数を各 2 回計測した。こ
の時、増殖阻害率はDay 3での細胞数からDay 0での細胞
数を差し引いた上で、薬剤未処理ディッシュ(ウェル)で
の細胞数に対する各濃度処理ディッシュ(ウェル)での細
胞数の比率を1から引いたものとし、各濃度あたり2枚の
ディッシュ(ウェル)での平均値として算出した。50%増
殖阻害濃度 (GI50) は各薬剤の濃度-増殖阻害率曲線か
ら内挿法により算出した。CPTに対する比活性 (relativ
e activity、以下RA) は同時に基準対照として試験した
CPTのGI50値を各薬剤のGI50値で除したもので表した。(2) Cell growth inhibitory activity measurement method In the system using KB, cells in the logarithmic growth phase were 2 × 10 4 on Day -1.
Cells / ml were diluted with the culture solution, and 3 ml was seeded in a 60 mm plastic dish (6 × 10 4 cells / dish). After culturing this overnight, it was replaced with a culture solution containing an appropriate concentration of each drug on Day 0, and culturing was continued for 3 days. After washing the cells with PBS (Nissui Pharmaceutical) on Day 3, the cells were detached from the dish using 0.5 ml of 0.25% trypsin solution (Gibco), and the whole amount was diluted to 10 ml with physiological saline. In the system using L1210, Da
Cells in the logarithmic growth phase were diluted with medium to 2 x 10 4 cells / ml in y 0, were implanted 0.5 ml per well in 24-well plastic plates (10 4 cells / well). After culturing this for 3 hours, a culture solution containing a double concentration of each drug was added at 0.5 ml / well, and culturing was continued for 3 days. On Day 3, all wells were diluted to 10 ml with saline. Cell suspension diluted in physiological saline was prepared using Coulter Counter (Type ZM, Coulter Electron
ics), the number of cells per 0.5 ml was measured twice each. At this time, the growth inhibition rate was calculated by subtracting the number of cells in Day 0 from the number of cells in Day 3 and the number of cells in each concentration-treated dish (well) with respect to the number of cells in the drug-untreated dish (well). The ratio was subtracted from 1 and calculated as the average value of two dishes (wells) for each concentration. The 50% growth inhibition concentration (GI 50 ) was calculated from the concentration-growth inhibition curve of each drug by interpolation. Specific activity to CPT (relativ
e activity (hereinafter RA) was also tested as a reference control
The CPT of GI 50 values expressed in divided by the GI 50 values of each agent.
【0018】PC-6、PC-6/SN2-5H、および HepG2 を用い
た系では MTT 法を用いた。 細胞を0.05% Trypsin-EDTA
(GIBCO BRL)により剥離し、5.5 x 103 cells/mlに調
製した細胞浮遊液を96-wellマイクロプレートに添加し
た (180 μl/well)。一晩、培養した後、各段階希釈し
た薬剤 (20 μl/well) を添加した。72時間培養後、5 m
g/ml の臭化3-(4,5-ジメチル-2-チアゾリル)-2,5-ジフ
ェニルテトラゾリウム(MTT、ナカライテスク)を20 μl/
well 添加し 4 時間培養後、遠心分離 (400 x g、10分)
し、細胞にジメチルスホキシドを 200 μl/well添加し
た。その後、波長570 nm、リファレンス波長 655 nm
での吸光度を測定した。この時、50% 増殖阻害濃度 (IC
50) は各薬剤の濃度-増殖率曲線から内挿法により算出
した。In the system using PC-6, PC-6 / SN2-5H and HepG2, the MTT method was used. Cells are 0.05% Trypsin-EDTA
(GIBCO BRL), and a cell suspension prepared at 5.5 × 10 3 cells / ml was added to a 96-well microplate (180 μl / well). After culturing overnight, the drug (20 μl / well) diluted in each step was added. After culturing for 72 hours, 5 m
g / ml of 3- (4,5-dimethyl-2-thiazolyl) -2,5-diphenyltetrazolium bromide (MTT, Nacalai Tesque) at 20 μl /
Add well and incubate for 4 hours, then centrifuge (400 xg, 10 minutes)
Then, 200 μl / well of dimethyl sulfoxide was added to the cells. After that, wavelength 570 nm, reference wavelength 655 nm
The absorbance at was measured. At this time, the 50% growth inhibitory concentration (IC
50 ) was calculated from the concentration-growth rate curve of each drug by interpolation.
【0019】(3)結果1 KB細胞に対する各種誘導体
の殺細胞作用 全てのCPT誘導体は 1 以上の RA 値を示した (表
4)。従って、全てのCPT誘導体は KB に対して、既
存の CPT よりも強力な殺細胞作用を示し、これらは抗
癌剤として利用し得る。(3) Results Cell killing effect of various derivatives on 1 KB cells All CPT derivatives showed RA values of 1 or more (Table 4). Therefore, all CPT derivatives show stronger cytocidal action against KB than existing CPT, and they can be used as anticancer agents.
【0020】(4)結果2 L1210に対する各種誘導体
の殺細胞作用 全てのCPT誘導体は 1 以上の RA 値を示した (表
4)。従って、全てのCPT誘導体は L1210 に対して、
既存の CPT よりも強力な殺細胞作用を示し、これらは
抗癌剤として利用し得る。(4) Result 2 Cell killing effect of various derivatives on L1210 All CPT derivatives showed RA values of 1 or more (Table 4). Therefore, all CPT derivatives are
It shows stronger cell killing effect than existing CPT, and these can be used as anticancer agents.
【0021】[0021]
【表4】 [Table 4]
【0022】(5)結果3 PC-6に対する各種誘導体の
殺細胞作用 PC6 に対する、本発明に用いられるCPT誘導体の IC
50 は SN-38 のそれに比べて小さかった (表5)。従っ
て、本発明に用いられるCPT誘導体は PC-6に対し
て、既存の強力な抗癌剤であるCPT-11の活性本体である
SN-38 よりも強力な殺細胞作用を示し、これらは抗癌
剤として利用し得る。(5) Result 3 Cell killing action of various derivatives on PC-6 IC of CPT derivative used in the present invention on PC6
50 was less than that of SN-38 (Table 5). Therefore, the CPT derivative used in the present invention is an active substance of CPT-11, which is an existing potent anticancer agent, with respect to PC-6.
It shows stronger cell killing effect than SN-38, and these can be used as anticancer agents.
【0023】3.各種誘導体のBCRPおよびMRP2に対する
作用 (1)SN-38耐性株PC-6/SN2-5Hに対する各種誘導体の殺
細胞作用 本発明に用いられるCPT誘導体の BCRP 過剰発現細胞
である PC6/SN2-5H に対するIC50 は SN-38に比べて小
さく、耐性癌細胞に対する比耐性値(RR)が小さかっ
た (表5)。従って、本発明に用いられるCPT誘導体
は、SN−38と比較してBCRP の基質となりにくく、
SN−38に対して耐性を有する癌細胞に対しても効果
を有する抗癌剤として利用し得る。3. Effects of Various Derivatives on BCRP and MRP2 (1) Cell Killing Action of Various Derivatives on SN-38 Resistant Strain PC-6 / SN2-5H The CPT derivative used in the present invention against PC6 / SN2-5H which is a BCRP overexpressing cell The IC 50 was smaller than that of SN-38, and the specific resistance value (RR) to resistant cancer cells was small (Table 5). Therefore, the CPT derivative used in the present invention is less likely to be a BCRP substrate than SN-38,
It can be used as an anticancer agent having an effect on cancer cells having resistance to SN-38.
【0024】[0024]
【表5】 [Table 5]
【0025】(2)HepG2に対する各種誘導体の殺細胞
作用 本発明に用いられるCPT誘導体の MRP2 過剰発現細胞
である HepG2 に対するIC50 は SN-38と同等以下だった
(表6)。従って、本発明に用いられるCPT誘導体は
MRP2 の基質となりにくい抗癌剤として利用し得る。[0025] (2) IC 50 on HepG2 is MRP2-overexpressing cells of CPT derivative used in the cell killing invention various derivatives on HepG2 was the equal to or less than the SN-38
(Table 6). Therefore, the CPT derivative used in the present invention is
It can be used as an anticancer drug that is unlikely to be a substrate for MRP2.
【0026】[0026]
【表6】 [Table 6]
【0027】以上より、本発明に用いられる CPT 誘導
体は強力な殺細胞作用を有し、かつBCRP、および MRP2
の基質となりにくいことが明らかになった。従って、本
発明に用いられるCPT誘導体は、抗癌剤に対して耐性
を獲得した癌細胞に対する効果が期待でき、耐性癌の治
療剤として利用し得る。As described above, the CPT derivative used in the present invention has a strong cell killing effect, and exhibits BCRP and MRP2
It became clear that it was difficult to become a substrate for the. Therefore, the CPT derivative used in the present invention can be expected to have an effect on cancer cells that have acquired resistance to an anticancer agent, and can be used as a therapeutic agent for resistant cancer.
【0028】[0028]
【発明の効果】本発明によれば、抗癌剤に耐性を有する
癌細胞に対して強い抗腫瘍活性を有する治療剤を得るこ
とができる。According to the present invention, a therapeutic agent having a strong antitumor activity against cancer cells having resistance to an anticancer agent can be obtained.
───────────────────────────────────────────────────── フロントページの続き (72)発明者 八重樫 ▼隆▲ 東京都港区東新橋1丁目1番19号 株式会 社ヤクルト本社内 (72)発明者 古田 富雄 東京都港区東新橋1丁目1番19号 株式会 社ヤクルト本社内 (72)発明者 永田 洋 東京都港区東新橋1丁目1番19号 株式会 社ヤクルト本社内 (72)発明者 田辺 信三 千葉県船橋市北本町2−25−6 (72)発明者 石川 智久 神奈川県横浜市緑区霧が丘4−17−30 (72)発明者 吉川 恵美 東京都町田市金井町3,133 藤の台団地 3−8−406 (72)発明者 早坂 進也 宮城県古川市西館1−7−35 (72)発明者 池上 洋二 埼玉県新座市栗原4−10−2−213 (72)発明者 岡 三喜男 長崎県長崎市御船蔵町16番43号1109 Fターム(参考) 4C050 AA01 BB04 CC07 DD02 EE02 FF02 GG02 GG03 GG04 4C086 AA01 AA02 AA03 CB22 MA01 MA04 NA14 ZB26 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yaegashi ▼ Takashi 1-1-19 Higashi-Shimbashi, Minato-ku, Tokyo Yakult Honsha (72) Inventor Tomio Furuta 1-1-1, Higashi-Shimbashi, Minato-ku, Tokyo No. 19 Yakult Honsha (72) Inventor Hiroshi Nagata 1-119 Higashi-Shimbashi, Minato-ku, Tokyo (72) Inventor Shinzo Tanabe 2- Kitahoncho, Funabashi-shi, Chiba 25-6 (72) Inventor Tomohisa Ishikawa 4-17-30 Kirigaoka, Midori-ku, Yokohama-shi, Kanagawa Prefecture (72) Inventor Emi Yoshikawa 3,133 Kanaicho, Machida-shi, Tokyo 3-8-406 Fujinodai Estate 3-8-406 (72) Inventor Shinya Hayasaka 1-35-35, Nishikan, Furukawa-shi, Miyagi (72) Inventor Yoji Ikegami 4-10-213, Kurihara, Niiza-shi, Saitama F-term (reference) 4C050 AA01 BB04 CC07 DD02 EE02 FF02 GG02 GG03 GG04 4C086 AA01 AA02 AA03 CB22 MA01 MA04 NA14 ZB26
Claims (2)
キル基、低級アルコキシル基または水酸基であり、Yは
水素、ハロゲン原子または水酸基であり、Xが水酸基でY
が水素のものを除く)で表されるカンプトテシン誘導体
を有効成分とする、抗癌剤耐性癌に対する治療剤。(1) Formula (1) (Wherein X is hydrogen, a halogen atom, an amino group, a lower alkyl group, a lower alkoxyl group or a hydroxyl group, Y is hydrogen, a halogen atom or a hydroxyl group, X is a hydroxyl group and Y
A therapeutic agent for an anticancer drug-resistant cancer, comprising a camptothecin derivative represented by the following formula:
T−11)に対する耐性癌である、請求項1に記載の治
療剤。2. The method according to claim 1, wherein the anticancer drug-resistant cancer is irinotecan hydrochloride (CP
The therapeutic agent according to claim 1, which is a cancer resistant to T-11).
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110872305A (en) * | 2019-11-22 | 2020-03-10 | 浙江工业大学 | Fluorocamptothecin medicament derivative and preparation and application thereof |
WO2021212638A1 (en) * | 2020-06-19 | 2021-10-28 | Hangzhou Dac Biotech Co., Ltd. | Conjugates of a cell-binding molecule with camptothecin analogs |
JP2022501341A (en) * | 2018-09-17 | 2022-01-06 | ザ・チルドレンズ・ホスピタル・オブ・フィラデルフィアThe Children’S Hospital Of Philadelphia | Polymer-based polymer prodrugs |
WO2023207773A1 (en) * | 2022-04-29 | 2023-11-02 | Shanghai Micurx Pharmaceutical Co., Ltd. | Ligand-drug conjugate of camptothecin analogs, intermediates, preparation method therefor, pharmaceutical composition and application thereof |
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JPH01186892A (en) * | 1988-01-20 | 1989-07-26 | Yakult Honsha Co Ltd | Novel comptothecin derivative |
WO1995028404A1 (en) * | 1994-04-19 | 1995-10-26 | Bionumerik Pharmaceuticals, Inc. | 7,11 disubstituted camptothecin derivatives, formulations containing such derivatives and their use |
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JPH01186892A (en) * | 1988-01-20 | 1989-07-26 | Yakult Honsha Co Ltd | Novel comptothecin derivative |
WO1995028404A1 (en) * | 1994-04-19 | 1995-10-26 | Bionumerik Pharmaceuticals, Inc. | 7,11 disubstituted camptothecin derivatives, formulations containing such derivatives and their use |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2022501341A (en) * | 2018-09-17 | 2022-01-06 | ザ・チルドレンズ・ホスピタル・オブ・フィラデルフィアThe Children’S Hospital Of Philadelphia | Polymer-based polymer prodrugs |
JP7546552B2 (en) | 2018-09-17 | 2024-09-06 | ザ・チルドレンズ・ホスピタル・オブ・フィラデルフィア | Polymer-based macromolecular prodrugs |
CN110872305A (en) * | 2019-11-22 | 2020-03-10 | 浙江工业大学 | Fluorocamptothecin medicament derivative and preparation and application thereof |
CN110872305B (en) * | 2019-11-22 | 2021-05-04 | 浙江工业大学 | Fluorocamptothecin medicament derivative and preparation and application thereof |
WO2021212638A1 (en) * | 2020-06-19 | 2021-10-28 | Hangzhou Dac Biotech Co., Ltd. | Conjugates of a cell-binding molecule with camptothecin analogs |
CN115443134A (en) * | 2020-06-19 | 2022-12-06 | 杭州多禧生物科技有限公司 | Conjugates of cell binding molecules and camptothecin analogs |
WO2023207773A1 (en) * | 2022-04-29 | 2023-11-02 | Shanghai Micurx Pharmaceutical Co., Ltd. | Ligand-drug conjugate of camptothecin analogs, intermediates, preparation method therefor, pharmaceutical composition and application thereof |
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