Panhandle PCR for cDNA: a rapid method for isolation of MLL fusion transcripts involving unknown partner genes.

Identifying translocations of the MLL gene at chromosome band 11q23 is important for the characterization and treatment of leukemia. However, cytogenetic analysis does not always find the translocations and the many partner genes of MLL make molecular detection difficult. We developed cDNA panhandle PCR to identify der(11) transcripts regardless of the partner gene. By reverse transcribing first-strand cDNAs with oligonucleotides containing coding sequence from the 5' MLL breakpoint cluster region at the 5' ends and random hexamers at the 3' ends, known MLL sequence was attached to the unknown partner sequence. This enabled the formation of stem-loop templates with the fusion point of the chimeric transcript in the loop and the use of MLL primers in two-sided PCR. The assay was validated by detection of the known fusion transcript and the transcript from the normal MLL allele in the cell line MV4-11. cDNA panhandle PCR then was used to identify the fusion transcripts in two cases of treatment-related acute myeloid leukemia where the karyotypes were normal and the partner genes unknown. cDNA panhandle PCR revealed a fusion of MLL with AF-10 in one case and a fusion of MLL with ELL in the other. Alternatively spliced transcripts and exon scrambling were detectable by the method. Leukemias with normal karyotypes may contain cryptic translocations of MLL with a variety of partner genes. cDNA panhandle PCR is useful for identifying MLL translocations and determining unknown partner sequences in the fusion transcripts.

Duplicated regions of AF-4 intron 4 at t(4;11) translocation breakpoints.

BACKGROUND: AF-4 is a common partner gene of MLL. AF-4 breakpoints occur in introns, but most AF-4 introns are uncharacterized. METHODS AND RESULTS: We cloned AF-4 intron 4 and examined the frequency of breakpoints in this intron. The 5.8-kb intron is rich in repeat sequences and was the site of translocation in 3 of 17 leukemias with t(4;11). We cloned the der (11) and der (4) breakpoints and isolated the fusion transcripts in the cell line MV4-11 and in a de novo acute lymphoblastic leukemia (ALL). Both translocations joined MLL intron 6 and AF-4 intron 4. In MV4-11, 249 bases from AF-4 were present in both derivative chromosomes, indicating duplication. In the de novo ALL, duplication of 446 bases from MLL and AF-4 occurred. Reciprocal fusion transcripts were expressed. CONCLUSIONS: Intronic sequence of AF-4 is useful for molecular diagnosis of t(4;11). Duplicated intronic regions suggest staggered chromosomal breakage.

MLL genomic breakpoint distribution within the breakpoint cluster region in de novo leukemia in children.

PURPOSE: To assess translocation breakpoint distribution within the MLL genomic breakpoint cluster region (bcr), 40 cases of de novo leukemia in children were examined by karyotype and Southern blot analysis. PATIENTS AND METHODS: Criteria for inclusion were karyotypic or molecular rearrangement of chromosome band 11q23. Of the 40 cases, 31 occurred in infants. Twenty cases were acute lymphoblastic leukemia (ALL), 17 were acute myeloid leukemia (AML), and 3 were biphenotypic. RESULTS: Karyotype identified 27 cases with translocation of chromosome band 11q23 and 2 with abnormalities of band 11q13 but not 11q23. Southern blot analysis showed rearrangement within the MLL genomic bcr in 38 of the 40 cases. In these 38, additional probe-restriction digest combinations localized MLL genomic breakpoints to the 5' portion of the bcr in 14 cases and to the 3' portion in 18; material was insufficient for further localization to 5' or 3' within the bcr in 6 cases. In the two remaining cases, both with t(4;11)(q21;q23), one breakpoint mapped 5' of the bcr between intron 3 and exon 5, whereas the other breakpoint was neither within nor 5' of the MLL genomic bcr. CONCLUSIONS: Suggested trends warranting investigation in more patients were breakpoint sites in the 3' bcr in AML and in patients older than 12 months. The distribution of MLL genomic breakpoints within the bcr in de novo leukemia in children is distinct from that in adults, where the breakpoints cluster in the 5' portion of the bcr.

Panhandle polymerase chain reaction amplifies MLL genomic translocation breakpoint involving unknown partner gene.

We used a new approach called panhandle polymerase chain reaction (PCR) to clone an MLL genomic translocation breakpoint in a case of acute lymphoblastic leukemia of infancy in which karyotype analysis was technically unsuccessful and did not show the translocation partner. Panhandle PCR amplified known MLL sequence 5' of the breakpoint and 3' sequence from the unknown partner gene from a DNA template with an intrastrand loop schematically shaped like a pan with a handle. The 7-kb panhandle PCR product contained the translocation breakpoint in MLL intron 8. The partner DNA included unique nonrepetitive sequences, Alu and mammalian apparent LTR-retrotransposon (MaLR) repetitive sequences, and a region of homology to expressed sequence tags. MaLR sequences have not been found before near leukemia-associated translocation breakpoints. The nonrepetitive sequences were not homologous to known partner genes of MLL. Screening of somatic cell hybrid and radiation hybrid lines by PCR and fluorescence in situ hybridization analysis of normal metaphase chromosomes mapped the partner DNA to chromosome band 4q21. Reverse transcriptase-PCR identified an MLL-AF-4 chimeric mRNA, indicating that panhandle PCR identified a fusion of MLL with a previously uncharacterized AF-4 intronic sequence. Panhandle PCR facilitates cloning translocation breakpoints and identifying unknown partner genes.

The p53 gene in pediatric therapy-related leukemia and myelodysplasia.

We investigated the frequency of p53 mutations in 19 pediatric cases of therapy-related leukemia or myelodysplastic syndrome. Eleven children presented with acute myeloid leukemia, one with mixed-lineage leukemia, two with acute lymphoblastic leukemia, and five with myelodysplasia at times ranging from 11 months to 9 years after a primary cancer diagnosis. The primary cancers, which included 11 solid tumors and eight leukemias, were treated with various combinations of DNA topoisomerase II inhibitors, alkylating agents, or irradiation. Leukemic or myelodysplastic marrows were screened for possible mutations by single-strand conformation polymorphism (SSCP) analysis of p53 exons 4 to 8. The only observed mutation was an inherited 2-basepair deletion at codon 209 in exon 6 that would shift the open reading frame, create a premature termination codon, and foreshorten the resultant protein. Prior therapy in this patient included DNA topoisomerase II inhibitors, alkylating agents, and irradiation. The secondary leukemia presented as myelodysplasia with monosomies of chromosomes 5 and 7 and abnormalities of chromosome 17. Although the primary cancer was an embryonal rhabdomyosarcoma and there was a family history of cancer, the case did not fulfill the clinical criteria for Li-Fraumeni syndrome. This study suggests that germline p53 mutations may predispose some children to therapy-related leukemia and myelodysplasia, but that p53 mutations otherwise are infrequent in this setting.