GGTase-I deficiency reduces tumor formation and improves survival in mice with K-RAS–induced lung cancer
Anna-Karin M. Sjogren, … , Stephen G. Young, Martin O. Bergo
Anna-Karin M. Sjogren, … , Stephen G. Young, Martin O. Bergo
Published May 1, 2007
Citation Information: J Clin Invest. 2007;117(5):1294-1304. https://doi.org/10.1172/JCI30868.
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Research Article

GGTase-I deficiency reduces tumor formation and improves survival in mice with K-RAS–induced lung cancer

Abstract

Protein geranylgeranyltransferase type I (GGTase-I) is responsible for the posttranslational lipidation of CAAX proteins such as RHOA, RAC1, and cell division cycle 42 (CDC42). Inhibition of GGTase-I has been suggested as a strategy to treat cancer and a host of other diseases. Although several GGTase-I inhibitors (GGTIs) have been synthesized, they have very different properties, and the effects of GGTIs and GGTase-I deficiency are unclear. One concern is that inhibiting GGTase-I might lead to severe toxicity. In this study, we determined the effects of GGTase-I deficiency on cell viability and K-RAS–induced cancer development in mice. Inactivating the gene for the critical β subunit of GGTase-I eliminated GGTase-I activity, disrupted the actin cytoskeleton, reduced cell migration, and blocked the proliferation of fibroblasts expressing oncogenic K-RAS. Moreover, the absence of GGTase-I activity reduced lung tumor formation, eliminated myeloproliferative phenotypes, and increased survival of mice in which expression of oncogenic K-RAS was switched on in lung cells and myeloid cells. Interestingly, several cell types remained viable in the absence of GGTase-I, and myelopoiesis appeared to function normally. These findings suggest that inhibiting GGTase-I may be a useful strategy to treat K-RAS–induced malignancies.

Authors

Anna-Karin M. Sjogren, Karin M.E. Andersson, Meng Liu, Briony A. Cutts, Christin Karlsson, Annika M. Wahlstrom, Martin Dalin, Carolyn Weinbaum, Patrick J. Casey, Andrej Tarkowski, Birgitta Swolin, Stephen G. Young, Martin O. Bergo

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Figure 5

Pggt1bfl/+KLSLLC mice develop lung cancer and hepatic leukocyte infiltration, and Pggt1b deficiency ameliorates these phenotypes.

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Pggt1bfl/+KLSLLC mice develop lung cancer and hepatic leukocyte infiltr...
(AK) H&E-stained sections of lung and liver. (A) Advanced adenoma in lung of a day 11 Pggt1bfl/+KLSLLC mouse. (B) Diffuse adenocarcinoma that obliterates the majority of alveolar spaces in lung of a day 20 Pggt1bfl/+KLSLLC mouse; inset shows Ki-67 immunostaining. (C) AAH lesions (arrows) in lung of a day 20 Pggt1bfl/flKLSLLC mouse. (D) Magnification of AAH lesion indicated by left arrow in C. (E) Papillary adenoma in lung of a day 98 Pggt1bfl/flKLSLLC mouse. (F) Magnification of E. (G) Normal lung of a day 11 control mouse. (H) Magnification of G. (I) Leukocyte infiltration in liver of a Pggt1bfl/+KLSLLC mouse; arrows indicate clusters of leukocytes. (J) Normal appearance of liver from a day 62 Pggt1bfl/flKLSLLC mouse. (K) Normal liver from a day 17 control mouse. Scale bars: 50 μm (A, inset in B, D, F, H, and I–K); 100 μm (B, C, E, and G). (L) Western blot showing high levels of nonprenylated RAP1 in lung tumors from Pggt1bfl/flKLSLLC mice (lanes 1–4) and Cre-adenovirus–treated Pggt1bfl/fl fibroblasts (lane 13) and lower levels in lung tissue from Pggt1bfl/flLC mice (lanes 9 and 10). Nonprenylated RAP1 was undetectable in lung tumors from Pggt1bfl/+KLSLLC mice (lanes 5–8), normal lung tissue of Pggt1bfl/+LC mice (lane 11), β-gal–adenovirus–treated Pggt1bfl/fl (lane 12) and Pggt1bfl/+ (lane 14) fibroblasts, and Cre-adenovirus–treated Pggt1bfl/+ fibroblasts (lane 15). Total ERK1/2 expression was analyzed on the same blot as a loading control. Protein extracts from an additional 4 tumors of Pggt1bfl/flKLSLLC mice and 2 tumors from Pggt1bfl/+KLSLLC mice were analyzed with similar results.