Biochemical Correlates of Temozolomide Sensitivity in Pediatric Solid Tumor Xenograft Models

Experimental Therapeutics, Preclinical Pharmacology

Biochemical Correlates of Temozolomide Sensitivity in Pediatric Solid Tumor Xenograft Models¹

David S. Middlemas², Clinton F. Stewart, Mark N Kirstein, Catherine Poquette, Henry S. Friedman, Peter J. Houghton and Thomas P. Brent

Departments of Molecular Pharmacology [D. S. M., P. J. H., T. P. B.], Pharmaceutical Science [C. F. S., M. N. K.], and Biostatistics and Epidemiology [C. P.], St. Jude Children’s Research Hospital, Memphis, Tennessee 38105, and Duke University Medical Center, Durham, North Carolina 27710 [H. S. F.]

The antitumor activity of the methylating agent temozolomidehas been evaluated against a panel of 17 xenografts derivedfrom pediatric solid tumors. Temozolomide was administered p.o.daily for five consecutive days at a dose level of 66 mg/kg.Courses of treatment were repeated every 21 days for three cycles.Tumor lines were classified as having high, intermediate, orlow sensitivity, determined by complete responses, partial responses,or stable disease, respectively. Overall, temozolomide inducedcomplete responses in five lines and partial responses in threeadditional tumor lines, giving objective regressions in 47%of xenograft lines. Analysis of temozolomide plasma systemic exposureindicated that this dose level was relevant to exposure achievedin patients. Tumors were analyzed by immunoblotting for levels ofO⁶-methylguanine-DNA methyltransferase (MGMT) and two mismatchrepair proteins, MLH-1 and MSH-2. Tumors classified as havinghigh or intermediate sensitivity had low or undetectable MGMTand expressed detectable MLH-1 and MSH-2 proteins. Tumors classifiedas having low sensitivity had either (a) high MGMT or (b) lowor undetectable MGMT but were deficient in MLH-1. The relationshipbetween p53 and response to temozolomide was also examined.In vitro temozolomide did not induce p21^cip1 in p53-competent NB-1643neuroblastoma cells. Suppression of p53 function in NB1643 clonesthrough stable expression of a trans dominant negative p53 (NB1643p53^TDN)did not confer temozolomide resistance. Similarly, tumor sensitivityto temozolomide did not segregate with p53 genotype or p53 functionalstatus. These results indicate that MGMT is the primary mechanismfor temozolomide resistance, but in the absence of MGMT, proficientmismatch repair determines sensitivity to this agent.

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