PURPOSE: To evaluate the potential of gene expression signatures to predict response to treatment in locally advanced cervical cancer treated with definitive chemotherapy and radiation. EXPERIMENTAL DESIGN: Tissue biopsies were collected from patients participating in Radiation Therapy Oncology Group (RTOG) 0128, a phase II trial evaluating the benefit of celecoxib in addition to cisplatin chemotherapy and radiation for locally advanced cervical cancer. Gene expression profiling was done and signatures of pretreatment, mid-treatment (before the first implant), and "changed" gene expression patterns between pre- and mid-treatment samples were determined. The ability of the gene signatures to predict local control versus local failure was evaluated. Two-group t test was done to identify the initial gene set separating these end points. Supervised classification methods were used to enrich the gene sets. The results were further validated by leave-one-out and 2-fold cross-validation. RESULTS: Twenty-two patients had suitable material from pretreatment samples for analysis, and 13 paired pre- and mid-treatment samples were obtained. The changed gene expression signatures between the pre- and mid-treatment biopsies predicted response to treatment, separating patients with local failures from those who achieved local control with a seven-gene signature. The in-sample prediction rate, leave-one-out prediction rate, and 2-fold prediction rate are 100% for this seven-gene signature. This signature was enriched for cell cycle genes. CONCLUSIONS: Changed gene expression signatures during therapy in cervical cancer can predict outcome as measured by local control. After further validation, such findings could be applied to direct additional therapy for cervical cancer patients treated with chemotherapy and radiation.
PURPOSE: To evaluate the potential of gene expression signatures to predict response to treatment in locally advanced cervical cancer treated with definitive chemotherapy and radiation. EXPERIMENTAL DESIGN: Tissue biopsies were collected from patients participating in Radiation Therapy Oncology Group (RTOG) 0128, a phase II trial evaluating the benefit of celecoxib in addition to cisplatin chemotherapy and radiation for locally advanced cervical cancer. Gene expression profiling was done and signatures of pretreatment, mid-treatment (before the first implant), and "changed" gene expression patterns between pre- and mid-treatment samples were determined. The ability of the gene signatures to predict local control versus local failure was evaluated. Two-group t test was done to identify the initial gene set separating these end points. Supervised classification methods were used to enrich the gene sets. The results were further validated by leave-one-out and 2-fold cross-validation. RESULTS: Twenty-two patients had suitable material from pretreatment samples for analysis, and 13 paired pre- and mid-treatment samples were obtained. The changed gene expression signatures between the pre- and mid-treatment biopsies predicted response to treatment, separating patients with local failures from those who achieved local control with a seven-gene signature. The in-sample prediction rate, leave-one-out prediction rate, and 2-fold prediction rate are 100% for this seven-gene signature. This signature was enriched for cell cycle genes. CONCLUSIONS: Changed gene expression signatures during therapy in cervical cancer can predict outcome as measured by local control. After further validation, such findings could be applied to direct additional therapy for cervical cancerpatients treated with chemotherapy and radiation.
Authors: R Pearcey; M Brundage; P Drouin; J Jeffrey; D Johnston; H Lukka; G MacLean; L Souhami; G Stuart; D Tu Journal: J Clin Oncol Date: 2002-02-15 Impact factor: 44.544
Authors: M Morris; P J Eifel; J Lu; P W Grigsby; C Levenback; R E Stevens; M Rotman; D M Gershenson; D G Mutch Journal: N Engl J Med Date: 1999-04-15 Impact factor: 91.245
Authors: P G Rose; B N Bundy; E B Watkins; J T Thigpen; G Deppe; M A Maiman; D L Clarke-Pearson; S Insalaco Journal: N Engl J Med Date: 1999-04-15 Impact factor: 91.245
Authors: T Sørlie; C M Perou; R Tibshirani; T Aas; S Geisler; H Johnsen; T Hastie; M B Eisen; M van de Rijn; S S Jeffrey; T Thorsen; H Quist; J C Matese; P O Brown; D Botstein; P E Lønning; A L Børresen-Dale Journal: Proc Natl Acad Sci U S A Date: 2001-09-11 Impact factor: 11.205
Authors: Pippa F Cosper; Christopher McNair; Iván González; Nathan Wong; Karen E Knudsen; Jason J Chen; Stephanie Markovina; Julie K Schwarz; Perry W Grigsby; Xiaowei Wang Journal: Int J Cancer Date: 2019-12-04 Impact factor: 7.396
Authors: David K Gaffney; Anuja Jhingran; Lorraine Portelance; Akila Viswanathan; Tracey Schefter; Joanne Weidhaas; William Small Journal: Int J Gynecol Cancer Date: 2014-06 Impact factor: 3.437
Authors: Charles A Kunos; Tomas Radivoyevitch; Steven Waggoner; Robert Debernardo; Kristine Zanotti; Kimberly Resnick; Nancy Fusco; Ramon Adams; Raymond Redline; Peter Faulhaber; Afshin Dowlati Journal: Gynecol Oncol Date: 2013-04-18 Impact factor: 5.482
Authors: Charles A Kunos; Kathryn Winter; Adam P Dicker; William Small; Fadi W Abdul-Karim; Dawn Dawson; Anuja Jhingran; Richard Valicenti; Joanne B Weidhaas; David K Gaffney Journal: Int J Gynecol Cancer Date: 2013-05 Impact factor: 3.437
Authors: Julianna K Bronk; Chiraag Kapadia; Xiaogang Wu; Bhavana V Chapman; Rui Wang; Tatiana V Karpinets; Xingzhi Song; Andrew M Futreal; Jianhua Zhang; Ann H Klopp; Lauren E Colbert Journal: PLoS One Date: 2022-10-06 Impact factor: 3.752