PURPOSE: The role of v-ATPases in cancer biology is being increasingly recognized. Yeast studies indicate that the tyrosine kinase inhibitor imatinib may interact with the v-ATPase genes and alter the course of cancer progression. Data from humans in this regard are lacking. METHODS: We constructed 55 lymphoblastoid cell lines from pedigreed, cancer-free human subjects and treated them with IC20 concentration of imatinib mesylate. Using these cell lines, we (i) estimated the heritability and differential expression of 19 genes encoding several subunits of the v-ATPase protein in response to imatinib treatment; (ii) estimated the genetic similarity among these genes; and (iii) conducted a high-density scan to find cis-regulating genetic variation associated with differential expression of these genes. RESULTS: We found that the imatinib response of the genes encoding v-ATPase subunits is significantly heritable and can be clustered to identify novel drug targets in imatinib therapy. Further, five of these genes were significantly cis-regulated and together represented nearly half-log fold change in response to imatinib (p = 0.0107) that was homogenous (p = 0.2598). CONCLUSIONS: Our results proffer support to the growing view that personalized regimens using proton pump inhibitors or v-ATPase inhibitors may improve outcomes of imatinib therapy in various cancers.
PURPOSE: The role of v-ATPases in cancer biology is being increasingly recognized. Yeast studies indicate that the tyrosine kinase inhibitor imatinib may interact with the v-ATPase genes and alter the course of cancer progression. Data from humans in this regard are lacking. METHODS: We constructed 55 lymphoblastoid cell lines from pedigreed, cancer-free human subjects and treated them with IC20 concentration of imatinib mesylate. Using these cell lines, we (i) estimated the heritability and differential expression of 19 genes encoding several subunits of the v-ATPase protein in response to imatinib treatment; (ii) estimated the genetic similarity among these genes; and (iii) conducted a high-density scan to find cis-regulating genetic variation associated with differential expression of these genes. RESULTS: We found that the imatinib response of the genes encoding v-ATPase subunits is significantly heritable and can be clustered to identify novel drug targets in imatinib therapy. Further, five of these genes were significantly cis-regulated and together represented nearly half-log fold change in response to imatinib (p = 0.0107) that was homogenous (p = 0.2598). CONCLUSIONS: Our results proffer support to the growing view that personalized regimens using proton pump inhibitors or v-ATPase inhibitors may improve outcomes of imatinib therapy in various cancers.
Authors: B D Mitchell; C M Kammerer; J Blangero; M C Mahaney; D L Rainwater; B Dyke; J E Hixson; R D Henkel; R M Sharp; A G Comuzzie; J L VandeBerg; M P Stern; J W MacCluer Journal: Circulation Date: 1996-11-01 Impact factor: 29.690
Authors: T Ohta; M Yamamoto; M Numata; S Iseki; H Kitagawa; M Kayahara; T Nagakawa; K Miwa; A Nakagawa; T Morise; S Ohkuma; T Terada Journal: Int J Oncol Date: 1997-09 Impact factor: 5.650
Authors: Hemant Kulkarni; Harald H H Göring; Vincent Diego; Shelley Cole; Ken R Walder; Greg R Collier; John Blangero; Melanie A Carless Journal: BMC Med Genomics Date: 2012-08-23 Impact factor: 3.063