PKD1 is the most common site for mutations in human autosomal dominant polycystic kidney disease (ADPKD). ADPKD is characterized by progressive replacement of kidney tissue by epithelial cysts and eventual renal failure. Hepatic and pancreatic cysts are also common. The PKD1 protein, polycystin, is a cell-surface protein of unknown function that is widely expressed in epithelia and in vascular smooth muscle and myocardium. None of the genetic forms of murine polycystic disease map to the murine Pkd1 locus. We introduced into mice by homologous recombination a Pkd1 truncation mutation, Pkd1-, that mimics a mutation found in ADPKD. Pkd1- heterozygotes have no discernible phenotype, whereas homozygotes die during the perinatal period with massively enlarged cystic kidneys, pancreatic ductal cysts and pulmonary hypoplasia. Renal cyst formation begins at embryonic day 15.5 (E15.5) in proximal tubules and progresses rapidly to replace the entire renal parenchyma. The timing of cyst formation indicates that full-length polycystin is required for normal morphogenesis during elongation and maturation of tubular structures in the kidney and pancreas.
Acquired imatinib resistance in advanced Philadelphia-positive acute lymphoblastic leukemia (Ph ؉ ALL) has been associated with mutations in the kinase domain (KD) of BCR-ABL. We examined the prevalence of KD mutations in newly diagnosed and imatinib-naive Ph ؉ ALL patients and assessed their clinical relevance in the setting of uniform frontline therapy with imatinib in combination with chemotherapy. Patients enrolled in the German Multicenter Study Group for Adult Acute Lymphoblastic Leukemia (GMALL) trial ADE10 for newly diagnosed elderly Ph ؉ ALL were retrospectively examined for the presence of BCR-ABL KD mutations by denaturing highperformance liquid chromatography (D-HPLC), cDNA sequencing, and allelespecific polymerase chain reaction (PCR). A KD mutation was detected in a minor subpopulation of leukemic cells in 40% of newly diagnosed and imatinib-naive patients. At relapse, the dominant cell clone harbored an identical mutation in 90% of cases, the overall prevalence of mutations at relapse was 80%. P-loop mutations predominated and were not associ-
IntroductionIncorporation of the ABL kinase inhibitor imatinib into frontline treatment of Philadelphia-positive acute lymphoblastic leukemia (Ph ϩ ALL) has significantly improved the antileukemic efficacy of induction therapy. Several cooperative ALL study groups have demonstrated complete remission rates consistently above 90%, irrespective of whether imatinib is used alone or combined with multiagent chemotherapy. [1][2][3][4][5][6][7][8][9] These results are superior to previously reported complete remission (CR) rates of 65% to 90% in younger patients [10][11][12][13] and 40% to 60% in Ph ϩ ALL patients older than 60 to 65 years of age. [14][15][16][17] Although accumulating evidence suggests that imatinib-containing therapeutic regimens may also improve long-term outcome in these patients, 3,[6][7][8]14 relapse remains a predominant cause of treatment failure. 3,[7][8][9] Numerous point mutations in the kinase domain (KD) of BCR-ABL that impair imatinib binding to varying degrees have been identified as a major mechanism of acquired resistance in patients with chronic myeloid leukemia (CML). [18][19][20][21][22][23][24][25] Data on BCR-ABL mutations in patients with Ph ϩ ALL or lymphoid blast crisis of CML are more limited. Two studies of patients with advanced Ph ϩ lymphoid leukemias identified 5 different KD mutations in 14 of the 17 evaluated patients with acquired resistance to imatinib. 26,27 Preponderance of the E255K/V P-loop mutation, which occurred in 6 of 9 patients (67%) following their treatment with imatinib was suggested by one of these reports 26 but not by the other. 27 However, all point mutations arose at positions within the KD that are known to be important for drug binding and to confer significant resistance to imatinib in vitro. [18][19][20] This demonstrated that different mutations within the BCR-ABL KD can be responsible for refractoriness of Ph ϩ lymphoid leukemias to imatinib, and also suggested that KD mutations may be a f...
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