Dept. of Radiation Oncology, University of Würzburg, Germany.
Bioorg Med Chem. 2013 Jul 1;21(13):3949-57. doi: 10.1016/j.bmc.2013.03.068. Epub 2013 Apr 12.
HIF-1α regulated genes are mainly responsible for tumour resistance to radiation- and chemo-therapy. Among these genes, carbonic anhydrase isoform IX (CA9) is highly over expressed in many types of cancer especially in high grade brain cancer like Glioblastoma (GBM). Inhibition of the enzymatic activity by application of specific chemical CA9 inhibitor sulphonamides (CAI) like Acetazolamide (Aza.), the new sulfonamide derivative carbonic anhydrase inhibitor (SU.D2) or indirect inhibitors like the HIF-1α inhibitor Chetomin or molecular inhibitors like CA9-siRNA are leading to an inhibition of the functional role of CA9 during tumorigenesis. Human GBM cells were treated with in vitro hypoxia (1, 6, or 24 h at 0.1%, O2). Aza. application was at a range between 250 and 8000 nM and the HIF-1α inhibitor Chetomin at a concentration range of 150-500 nM. Cell culture plates were incubated for 24 h under hypoxia (0.1% O2). Further, CA9-siRNA constructs were transiently transfected into GBM cells exposed to extreme hypoxic aeration conditions. CA9 protein expression level was detectable in a cell-type specific manner under normoxic conditions. Whereas U87-MG exhibited a strong aerobic expression, U251 and U373 displayed moderate and GaMG very weak normoxic CA9 protein bands. Aza. as well as SU.D2 displayed inhibitory characteristics to hypoxia induced CA9 expression in the four GBM cell lines for 24 h of hypoxia (0.1% O2) at concentrations between 3500 and 8000 nM, on both the protein and mRNA level. Parallel experiments using CA9-siRNA confirmed these results. Application of 150-500 nM of the glycolysis inhibitor Chetomin under similar oxygenation conditions led to a sharply reduced expression of both CA IX protein and CA9 mRNA levels, indicating a clear glucose availability involvement for the hypoxic HIF-1α and CA9 expression in GBM cells. Hypoxia significantly influences the behaviour of human tumour cells by activation of genes involved in the adaptation to hypoxic stress. The main objective in malignant GBM therapy is either to eradicate the tumour or to convert it into a controlled, quiescent chronic disease. Aza., SU.D2, Chetomin or CA9-siRNA possesses functional CA9 inhibitory characteristics when applied against human cancers with hypoxic regions like GBM. They may be used as alternative or in conjunction with other direct inhibitors possessing similar functionality, thereby rendering them as potential optimal tools for the development of an optimized therapy in human brain cancer treatment.
HIF-1α 调节的基因主要负责肿瘤对放疗和化疗的耐药性。在这些基因中,碳酸酐酶同工酶 IX(CA9)在许多类型的癌症中高度过表达,特别是在高级别脑癌如胶质母细胞瘤(GBM)中。通过应用特定的化学 CA9 抑制剂磺胺类药物(CAI)如乙酰唑胺(Aza.)、新型磺胺衍生物碳酸酐酶抑制剂(SU.D2)或间接抑制剂如 HIF-1α 抑制剂 Chetomin 或分子抑制剂如 CA9-siRNA 来抑制 CA9 的酶活性,从而在肿瘤发生过程中抑制 CA9 的功能作用。将人 GBM 细胞进行体外缺氧处理(0.1%O2 下 1、6 或 24 小时)。Aza. 的应用范围在 250 到 8000 nM 之间,HIF-1α 抑制剂 Chetomin 的浓度范围在 150-500 nM 之间。将细胞培养板在缺氧条件下(0.1%O2)孵育 24 小时。进一步将 CA9-siRNA 构建体瞬时转染到暴露于极端低氧通气条件下的 GBM 细胞中。在常氧条件下,CA9 蛋白表达水平以细胞类型特异性方式可检测到。而 U87-MG 表现出强烈的需氧表达,U251 和 U373 显示出中等程度的表达,而 GaMG 则表现出非常弱的常氧 CA9 蛋白条带。在四种 GBM 细胞系中,Aza. 和 SU.D2 在浓度为 3500 到 8000 nM 之间,在蛋白和 mRNA 水平上均显示出抑制缺氧诱导的 CA9 表达的特征,持续 24 小时的缺氧(0.1%O2)。使用 CA9-siRNA 的平行实验证实了这些结果。在类似的氧合条件下应用 150-500 nM 的糖酵解抑制剂 Chetomin 可导致 CAIX 蛋白和 CA9 mRNA 水平的表达明显降低,这表明在 GBM 细胞中,葡萄糖的可用性对缺氧 HIF-1α 和 CA9 的表达有明显的影响。缺氧通过激活参与适应低氧应激的基因显著影响人类肿瘤细胞的行为。恶性 GBM 治疗的主要目标是要么根除肿瘤,要么将其转化为可控的、静止的慢性疾病。在具有缺氧区域的人类癌症中,Aza.、SU.D2、Chetomin 或 CA9-siRNA 具有功能性 CA9 抑制特征。它们可作为替代物或与具有类似功能的其他直接抑制剂一起使用,从而使它们成为开发人类脑癌治疗优化治疗的潜在最佳工具。
