6-(3-hydroxypropyl)-5H-indeno[1,2-c]isoquinoline-5,11(6H)-dione
中文名称
——
中文别名
——
英文名称
6-(3-hydroxypropyl)-5H-indeno[1,2-c]isoquinoline-5,11(6H)-dione
英文别名
6-(3-hydroxypropyl)-6H-indeno[1,2-c]isoquinoline-5,11-dione;6-(3-hydroxypropyl)indeno[1,2-c]isoquinoline-5,11-dione
![6-(3-hydroxypropyl)-5H-indeno[1,2-c]isoquinoline-5,11(6H)-dione化学式](data:image/svg+xml;base64,<?xml version="1.0" encoding="UTF-8"?>
<svg xmlns="http://www.w3.org/2000/svg" xmlns:xlink="http://www.w3.org/1999/xlink" width="300" height="300" viewBox="0 0 300 300">
<defs>
<g>
<g id="glyph-0-0">
<path d="M 0.875 3.125 L 0.875 -12.4375 L 9.703125 -12.4375 L 9.703125 3.125 Z M 1.875 2.140625 L 8.71875 2.140625 L 8.71875 -11.453125 L 1.875 -11.453125 Z M 1.875 2.140625 "/>
</g>
<g id="glyph-0-1">
<path d="M 1.734375 -12.859375 L 4.078125 -12.859375 L 9.78125 -2.109375 L 9.78125 -12.859375 L 11.46875 -12.859375 L 11.46875 0 L 9.125 0 L 3.421875 -10.765625 L 3.421875 0 L 1.734375 0 Z M 1.734375 -12.859375 "/>
</g>
<g id="glyph-0-2">
<path d="M 6.953125 -11.6875 C 5.691406 -11.6875 4.6875 -11.210938 3.9375 -10.265625 C 3.195312 -9.328125 2.828125 -8.046875 2.828125 -6.421875 C 2.828125 -4.796875 3.195312 -3.507812 3.9375 -2.5625 C 4.6875 -1.625 5.691406 -1.15625 6.953125 -1.15625 C 8.210938 -1.15625 9.210938 -1.625 9.953125 -2.5625 C 10.691406 -3.507812 11.0625 -4.796875 11.0625 -6.421875 C 11.0625 -8.046875 10.691406 -9.328125 9.953125 -10.265625 C 9.210938 -11.210938 8.210938 -11.6875 6.953125 -11.6875 Z M 6.953125 -13.09375 C 8.753906 -13.09375 10.191406 -12.488281 11.265625 -11.28125 C 12.347656 -10.070312 12.890625 -8.453125 12.890625 -6.421875 C 12.890625 -4.390625 12.347656 -2.769531 11.265625 -1.5625 C 10.191406 -0.351562 8.753906 0.25 6.953125 0.25 C 5.140625 0.25 3.691406 -0.351562 2.609375 -1.5625 C 1.523438 -2.769531 0.984375 -4.390625 0.984375 -6.421875 C 0.984375 -8.453125 1.523438 -10.070312 2.609375 -11.28125 C 3.691406 -12.488281 5.140625 -13.09375 6.953125 -13.09375 Z M 6.953125 -13.09375 "/>
</g>
<g id="glyph-0-3">
<path d="M 1.734375 -12.859375 L 3.46875 -12.859375 L 3.46875 -7.59375 L 9.796875 -7.59375 L 9.796875 -12.859375 L 11.53125 -12.859375 L 11.53125 0 L 9.796875 0 L 9.796875 -6.125 L 3.46875 -6.125 L 3.46875 0 L 1.734375 0 Z M 1.734375 -12.859375 "/>
</g>
</g>
</defs>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.93983 3.000214 L 2.93983 2.000043 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.773105 2.879201 L 2.773105 2.121233 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.946828 2.997911 L 1.981827 3.312313 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.933363 2.996493 L 3.551006 3.352976 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.933363 2.003763 L 3.814204 1.495085 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.946828 2.002346 L 1.977397 1.68812 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.988914 3.31001 L 1.401036 2.499951 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.797473 3.330031 L 1.322724 2.675889 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.991926 3.303189 L 1.57786 4.231868 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.060836 3.352976 L 4.680429 2.995341 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.805877 3.755879 L 3.805877 4.508621 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.805877 1.499868 L 4.672101 2.000043 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.972602 1.403661 L 4.672101 1.807627 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.805877 1.509525 L 3.805877 0.490218 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.996001 1.682096 L 1.396696 2.505975 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.086805 1.723645 L 1.853904 1.005984 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.928319 1.775203 L 1.695418 1.057366 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.408389 2.499242 L 0.397145 2.605992 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.591414 4.222124 L 0.577246 4.329139 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.478286 4.066473 L 0.655559 4.15329 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.672101 3.009782 L 4.672101 1.990475 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.588739 3.048318 L 5.220557 3.413039 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.672101 2.904006 L 5.30383 3.268728 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.797549 4.494181 L 4.680429 5.004011 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.663774 2.004915 L 5.54621 1.495085 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.797549 0.504658 L 4.680429 -0.00481778 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.964186 0.600866 L 4.680429 0.187598 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.410699 2.596247 L -0.00389845 3.527674 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.523827 2.75181 L 0.187454 3.507652 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.592484 4.335872 L -0.00567023 3.511107 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.672101 4.989571 L 4.672101 6.008878 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 5.537883 1.509525 L 5.537883 0.490218 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 5.371247 1.413317 L 5.371247 0.586426 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.663774 -0.00481778 L 5.54621 0.504658 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.663774 5.994438 L 5.262193 6.339935 " transform="matrix(44.094013, 0, 0, 44.094013, 18.761742, 2.849154)"/>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="179.980469" y="163.609375"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="85.898438" y="41.890625"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="256.011719" y="163.601562"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="256.011719" y="295.839844"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-3" x="268.640625" y="295.609375"/>
</g>
</svg>
)
CAS
——
化学式
C19H15NO3
mdl
——
分子量
305.333
InChiKey
AEVCRSQXDKOUMY-UHFFFAOYSA-N
BEILSTEIN
——
EINECS
——
-
物化性质
-
计算性质
-
ADMET
-
安全信息
-
SDS
-
制备方法与用途
-
上下游信息
-
文献信息
-
表征谱图
-
同类化合物
-
相关功能分类
-
相关结构分类
计算性质
-
辛醇/水分配系数(LogP):2.1
-
重原子数:23
-
可旋转键数:3
-
环数:4.0
-
sp3杂化的碳原子比例:0.16
-
拓扑面积:57.6
-
氢给体数:1
-
氢受体数:3
上下游信息
-
上游原料
中文名称 英文名称 CAS号 化学式 分子量 苯并[d]茚并[1,2-b]吡喃-5,11-二酮 6-Oxa-benzo[a]fluorene-5,11-dione 5651-60-5 C16H8O3 248.238 -
下游产品
中文名称 英文名称 CAS号 化学式 分子量 —— 6-(2-carboxy-1-ethyl)-5,6-dihydro-5,11-dioxo-11H-indeno[1,2-c]isoquinoline —— C19H13NO4 319.317 —— 3-{5,11-dioxo-5H,6H,11H-indeno[1,2-c]isoquinolin-6-yl}propyl 4-methylbenzene-1-sulfonate 1259520-40-5 C26H21NO5S 459.522
反应信息
-
作为反应物:描述:6-(3-hydroxypropyl)-5H-indeno[1,2-c]isoquinoline-5,11(6H)-dione 在 Jonea reagent 作用下, 以 丙酮 为溶剂, 以99%的产率得到6-(2-carboxy-1-ethyl)-5,6-dihydro-5,11-dioxo-11H-indeno[1,2-c]isoquinoline参考文献:名称:新的茚并[1,2-c]异喹啉的合成:细胞毒性非喜树碱拓扑异构酶I抑制剂。摘要:为了设计和合成通过抑制拓扑异构酶I(top1)发挥作用的潜在抗癌药,制备了一系列新的茚并异喹啉并测试了其在人类癌细胞培养中的细胞毒性以及对top1的活性。该合成依赖于取代的席夫碱与高邻苯二甲酸酐的缩合,以产生顺式-3-芳基-4-羧基异喹啉酮,其在亚硫酰氯存在下环化成茚并异喹啉。在单个化合物6- [3-(2-羟乙基)氨基丙基] -5,6-二氢-2,3-二甲氧基-8,9-亚甲基二氧基-5,11-二氧代-11H中,top1的抑制活性和细胞毒性均最大化。 -茚并[1,2-c]异喹啉盐酸盐(19a)被证明是一种非常有效的top1抑制剂,在55种人类癌细胞培养物中进行细胞毒性测试时,其平均图中点(MGM)为110 nM。还获得了许多与结构相关的茚并异喹啉,它们既具有有效的细胞毒性,又具有top1抑制活性。更有效的化合物的关键特征是在茚并异喹啉氮原子上存在氨基烷基侧链。在存在茚并异喹啉的情况下,top1DOI:10.1021/jm000029d
-
作为产物:描述:2-(2-Carboxyphenyl)-1,3-indandion 在 水 、 对甲苯磺酸 作用下, 以 氯仿 、 苯 为溶剂, 反应 7.0h, 生成 6-(3-hydroxypropyl)-5H-indeno[1,2-c]isoquinoline-5,11(6H)-dione参考文献:名称:首个双酪氨酰-DNA 磷酸二酯酶 I (Tdp1)-拓扑异构酶 I (Top1) 抑制剂的合成和生物学评价摘要:在一种低分子量化合物中具有双重酪氨酰-DNA 磷酸二酯酶 I-拓扑异构酶 I 抑制活性的物质将构成一类独特的抗癌剂,可能比针对单个酶的药物具有显着的优势。本研究证明了基于茚并异喹啉化学型的第一个双 Top1-Tdp1 抑制剂的成功合成和评估。一种双(茚并异喹啉)对人 Tdp1 具有显着活性(IC 50= 1.52 ± 0.05 μM),并且作为 Top1 抑制剂与喜树碱等效。通过该系列的结构-活性关系研究,获得了对酶-药物相互作用的重要见解。目前的结果还证明了先前报道的磺酰酯药效团未能在这种茚并异喹啉类抑制剂中赋予 Tdp1 抑制作用,尽管它被证明对类固醇 NSC 88915 有效 ( 7 )。目前的研究将促进未来优化双 Top1-Tdp1 抑制剂的努力。DOI:10.1021/jm300335n
文献信息
-
SYNTHESIS AND USE OF DUAL TYROSYL-DNA PHOSPHODIESTERASE I (TDP1)- TOPOISOMERASE I (TOP1) INHIBITORS申请人:PURDUE RESEARCH FOUNDATION公开号:US20130345252A1公开(公告)日:2013-12-26The invention described herein pertains to the synthesis and use of certain N-substituted indenoisoquinoline compounds which inhibit the activity Tyrosyl-DNA Phosphodiesterase I (Tdp1) or Topoisomerase I (Top1) or both, or otherwise demonstrate anticancer activity. Also disclosed are novel N-substituted indenoisoquinoline compounds and pharmaceutical compositions comprising the novel N-substituted indenoisoquinoline compounds.本发明涉及合成和使用某些N-取代吲哚异喹啉化合物,这些化合物抑制酪氨酸-DNA磷酸二酯酶I(Tdp1)或拓扑异构酶I(Top1)或两者的活性,或表现出抗癌活性。还公开了新颖的N-取代吲哚异喹啉化合物和包含这些新颖的N-取代吲哚异喹啉化合物的药物组合物。
-
Rhodium-Catalyzed [4 + 2] Cascade Annulation to Easy Access N-Substituted Indenoisoquinolinones作者:Xuelin Yue、Yijie Gao、Junwei Huang、Yadong Feng、Xiuling CuiDOI:10.1021/acs.orglett.3c01032日期:2023.4.28An efficient approach for the synthesis of N-substituted indenoisoquinolinones via rhodium(III)-catalyzed C–H bond activation/subsequent [4 + 2] cyclization starting from easily available 2-phenyloxazolines and 2-diazo-1,3-indandiones has been developed. A series of indeno[1,2-c]isoquinolinones were obtained in up to 93% yield through C–H functionalization, followed by intramolecular annulation, elimination一种通过铑 (III) 催化的 C-H 键活化/随后的 [4 + 2] 环化合成 N-取代茚并异喹啉酮的有效方法,从容易获得的 2-苯基恶唑啉和 2-重氮-1,3-茚满二酮开始发达。通过C-H功能化,然后在温和的反应条件下以“一锅法”进行分子内环化、消除和开环,获得了一系列茚并[1,2-c]异喹啉酮,收率高达93 % 。该协议具有出色的原子和步骤经济性,为合成 N-取代茚并异喹啉酮提供了一种新策略,并有机会研究它们的生物活性。
-
一种N-取代茚并异喹啉酮衍生物及其制备方法申请人:华侨大学公开号:CN115108987B公开(公告)日:2023-05-26本发明公开了一种N‑取代茚并异喹啉酮衍生物及其制备方法,其结构式为本发明的N‑取代的茚并异喹啉酮衍生物从药物化学的角度上具有深远的意义;所用原料易得,收率高,反应条件温和,底物范围广,后处理简便。
-
Indeno[1,2-c]isoquinolin-5,11-diones conjugated to amino acids: Synthesis, cytotoxicity, DNA interaction, and topoisomerase II inhibition properties作者:Gang Ahn、Amélie Lansiaux、Jean-François Goossens、Christian Bailly、Brigitte Baldeyrou、Nadège Schifano-Faux、Pierre Grandclaudon、Axel Couture、Adina RyckebuschDOI:10.1016/j.bmc.2010.08.025日期:2010.11.15Three series of indeno[1,2-c]isoquinolin-5,11-dione-amino acid conjugates were designed and synthesized. Amino acids were connected to the tetracycle through linkers with lengths of n = 2 and 3 atoms using ester (series I), amide (series II), and secondary amine (series III) functions. DNA binding was evaluated by thermal denaturation and fluorescence measurements. Lysine and arginine substituted derivatives with n = 3 provided the highest DNA binding. Arginine derivative 32 (n = 2, series II) and glycine derivative 34 (n = 2, series III) displayed high topoisomerase II inhibition. Incrementing the length of the N-6 side chain from two to three methylene units provided a significant increase in DNA affinity but a substantial loss in topoisomerase II inhibition. The most cytotoxic compounds toward HL60 leukemia cells were 19, 33, and 34 displaying micromolar IC50 values. When tested with the topoisomerase II-mutated HL60/MX2 cell line, little variation of IC50 values was found, suggesting that topoisomerase II might not be the main target of these compounds and that additional targets could be involved. (C) 2010 Elsevier Ltd. All rights reserved.
-
US8912213B2申请人:——公开号:US8912213B2公开(公告)日:2014-12-16
同类化合物
(4-(4-氯苯基)硫代)-10-甲基-7H-benzimidazo(2,1-A)奔驰(德)isoquinolin-7一
高氯酸9-碘-11-甲基吡啶并[1,2-b]异喹啉正离子
高唐碱
降氧化北美黄连次碱
阿莫伦特
阿曲库铵杂质N
阿曲库铵杂质J
阿曲库铵杂质I
阿曲库铵杂质F
阿曲库铵杂质E
阿曲库铵杂质E
阿曲库铵杂质D
阿曲库铵杂质C
阿曲库铵杂质A
阿曲库铵杂质48
阿曲库铵
阿司他丁
长茎唐松碱
贝马力农
衡州乌药碱; 乌药碱
蝙蝠葛碱
蝙蝠葛新林碱
蒂巴因水杨酸盐
葡萄孢镰菌素
萘酞磷
萘氨磷
萘亚胺
莲心季铵碱
莲子心碱
莫沙维林
苯磺顺阿曲库铵杂质23
苯磺安托肌松
苯并咪唑并[2,1-A]苯并[D,E]异奎千酮-7-酮
苯并[g]异喹啉-5,10-二酮
苯并[f]异喹啉-4(3h)-酮
苯并[f]异喹啉
苯并[c][1,8]萘啶-6(5h)-酮
苯并[b]喹嗪鎓溴化物
苯基异喹啉-6-基氨基甲酸酯
苄氧基羰基酪氨酰-赖氨酰-精氨酸-4-硝基苯胺
苄叉异喹酮
艳红淀R
肌氨酰-020106
网状盐酸盐酸盐
罌粟啶
罂粟碱硫酸盐
罂粟碱月桂基硫酸盐
罂粟碱亚硝酸盐
罂粟碱
罂粟林
联系我们
关注我们
公众号
