Summary. The AF-4 gene on human chromosome 4q21 is involved in reciprocal translocations to the ALL-1 gene on chromosome 11q23, which are associated with acute lymphoblastic leukaemias. A set of recombinant phage carrying genomic fragments for the coding region and flanking sequences of the AF-4 gene were isolated. Phage inserts were assembled into four contigs with 21 exons, and an intron phase map was produced enabling the interpretation of translocation-generated fusion proteins. The gene contains two alternative first exons, 1a and 1b, both including a translation initiation codon. The translocation breakpoint cluster region is flanked by exons 3 and 6 and two different polyadenylation signals were identified. Polyclonal antisera directed against three different portions of the AF-4 protein were produced and used to detect a 116 kD protein in cellular extracts of human B-lymphoblastoid and proB cell lines. In mitogen-stimulated human peripheral blood mononuclear cells the AF-4 antigen was predominantly located in the nucleus. The AF-4 gene is a member of the AF-4, LAF-4 and FMR-2 gene family. The members of this family encode serine-proline-rich proteins with properties of nuclear transcription factors. Comparison of AF-4 protein coding sequences with the LAF-4 and FMR-2 sequences revealed five highly conserved domains of potential functional relevance.
The acute lymphoblastic leukaemia (ALL)-1 gene on human chromosome 11q23 is the site of many locally clustered chromosomal alterations associated with several types of acute leukaemias, including deletions, partial duplications and translocations. Structurally variant proteins derived from the altered gene presumably cause the malignant transformation of early haemopoietic progenitor cells. According to previously published reports, the gene consisted of at least 21 exons spread over approximately 100 kb. In this report a set of genomic fragments was isolated that represent a total of 35 exons (exons 3-37) encompassing > 95% of the protein-coding region (except exons 1 and 2) and the 3'-non-translated region of the gene. The distances between these exons were determined and a detailed restriction map was produced. The majority of the exon/intron boundaries were sequenced and an intron-phase analysis was performed. The results form the basis for a greater understanding of the translocations and other structural alterations of the gene that conserve the open reading frame and thus produce presumably oncogenic variants of the ALL-1 protein.
Chromosomal translocations t(4;11) are regularly associated with a speci®c type of acute leukemias and probably initiate the development of this disease. It has been proposed by others, that these translocations are mediated by recombinases of the immune system. The breakpoints on both derivative chromosomes for three t(4;11) leukemia-derived cell lines and primary blasts from two patients have been analysed here in detail. The results revealed that: (a) multiple double-or singlestranded DNA breaks must have occured near the translocation breakpoints on both participating chromosomes; and (b) DNA fragments¯anked by these breaks must have either been deleted, inverted or duplicated during the translocation process. We found no evidence for the involvement of speci®c target sequences and recombinases of the immune system. Similar characteristic features were observed by re-interpretation of published t(6;11) and t(9;22) translocation data. Therefore we present a new model for the generation of these translocations which poses, that these translocations are reciprocal but not balanced at the ®ne structure level and that the DNA damage-repair machinery is likely involved in producing the ®nal structure of the translocation breakpoint.
The chromosomal breakpoint and fusion transcripts of the pre-B-leukaemia-derived SEM cell line carrying a reciprocal t(4;11)(q21;q23) translocation were analysed. The breakpoint from derivative chromosome der4 was cloned and sequenced. The crossover site was localized in intron 7 of the ALL-1 gene on chromosome 11q23 and in a large intron of the AF-4 (FEL) gene. RNA transcripts from both wild-type genes and both hybrid genes were detected by reverse transcriptase polymerase chain reaction (RT-PCR) assays. In addition, alternatively spliced mRNA species derived from the der4 chromosome were found. They were generated by using the exon 5' of the breakpoint on der4 as a common splice donor site and the 5' boundaries of exons 8 or 9 of the ALL-1 gene as alternative splice acceptor sites. The hypothesis is proposed that selective pressure operators to maintain the presence of both derivative chromosomes as important elements in the leukaemogenic process.
The human ALL-1/MLL/HRX gene on chromosome 11q23 is the site of many locally clustered chromosomal alterations associated with several types of acute leukemias, including deletions. partial duplications and reciprocal translocations. Structurally variant proteins derived from an altered ALL-1 gene presumably make essential contributions to the malignant transformation of hematopoietic progenitor cells. The ALL-1 gene is spread over approximately 92 kb and consists of at least 37 exons. An exon/intron map including the position of the 3'-end of the gene and a detailed restriction map were produced and an updated map is presented. Data from other laboratories were incorporated where compatible. Exon/intron boundaries were sequenced and an intron-phase analysis was performed. The results are expected to contribute to a better understanding of those structural alterations of the gene that conserve the open reading frame and produce presumably oncogenic variants of the ALL-1 protein. They will also facilitate the rapid molecular diagnosis of structural alterations of this gene and the choice of therapeutic options. Mechanisms that may potentially account for the striking clustering of the translocation breakpoints in the breakpoint cluster region of the gene are discussed.
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