Thorsen Kasper, Sørensen Karina D, Brems-Eskildsen Anne Sofie, Modin Charlotte, Gaustadnes Mette, Hein Anne-Mette K, Kruhøffer Mogens, Laurberg Søren, Borre Michael, Wang Kai, Brunak Søren, Krainer Adrian R, Tørring Niels, Dyrskjøt Lars, Andersen Claus L, Orntoft Torben F
Molecular Diagnostic Laboratory, Department of Clinical Biochemistry, Aarhus University Hospital, Skejby, DK-8200 Aarhus N, Denmark.
Mol Cell Proteomics. 2008 Jul;7(7):1214-24. doi: 10.1074/mcp.M700590-MCP200. Epub 2008 Mar 18.
Alternative splicing enhances proteome diversity and modulates cancer-associated proteins. To identify tissue- and tumor-specific alternative splicing, we used the GeneChip Human Exon 1.0 ST Array to measure whole-genome exon expression in 102 normal and cancer tissue samples of different stages from colon, urinary bladder, and prostate. We identified 2069 candidate alternative splicing events between normal tissue samples from colon, bladder, and prostate and selected 15 splicing events for RT-PCR validation, 10 of which were successfully validated by RT-PCR and sequencing. Furthermore 23, 19, and 18 candidate tumor-specific splicing alterations in colon, bladder, and prostate, respectively, were selected for RT-PCR validation on an independent set of 81 normal and tumor tissue samples. In total, seven genes with tumor-specific splice variants were identified (ACTN1, CALD1, COL6A3, LRRFIP2, PIK4CB, TPM1, and VCL). The validated tumor-specific splicing alterations were highly consistent, enabling clear separation of normal and cancer samples and in some cases even of different tumor stages. A subset of the tumor-specific splicing alterations (ACTN1, CALD1, and VCL) was found in all three organs and may represent general cancer-related splicing events. In silico protein predictions suggest that the identified cancer-specific splice variants encode proteins with potentially altered functions, indicating that they may be involved in pathogenesis and hence represent novel therapeutic targets. In conclusion, we identified and validated alternative splicing between normal tissue samples from colon, bladder, and prostate in addition to cancer-specific splicing events in colon, bladder, and prostate cancer that may have diagnostic and prognostic implications.
可变剪接增强了蛋白质组的多样性,并调节与癌症相关的蛋白质。为了鉴定组织特异性和肿瘤特异性的可变剪接,我们使用基因芯片人类外显子1.0 ST阵列来测量来自结肠、膀胱和前列腺的102个不同阶段的正常和癌症组织样本中的全基因组外显子表达。我们鉴定了结肠、膀胱和前列腺正常组织样本之间的2069个候选可变剪接事件,并选择了15个剪接事件进行RT-PCR验证,其中10个通过RT-PCR和测序成功验证。此外,分别在81个正常和肿瘤组织样本的独立集合上选择了结肠、膀胱和前列腺中23个、19个和18个候选肿瘤特异性剪接改变进行RT-PCR验证。总共鉴定出7个具有肿瘤特异性剪接变体的基因(ACTN1、CALD1、COL6A3、LRRFIP2、PIK4CB、TPM1和VCL)。经过验证的肿瘤特异性剪接改变高度一致,能够清晰区分正常和癌症样本,在某些情况下甚至能区分不同的肿瘤阶段。在所有三个器官中都发现了一部分肿瘤特异性剪接改变(ACTN1、CALD1和VCL),它们可能代表一般的癌症相关剪接事件。计算机模拟蛋白质预测表明,所鉴定的癌症特异性剪接变体编码的蛋白质功能可能发生改变,这表明它们可能参与发病机制,因此代表新的治疗靶点。总之,我们鉴定并验证了结肠、膀胱和前列腺正常组织样本之间的可变剪接,以及结肠、膀胱和前列腺癌中可能具有诊断和预后意义的癌症特异性剪接事件。
