Acute promyelocytic leukaemia (APL), associated with chromosomal translocations involving the retinoic acid receptor alpha gene (RARA) and the PML gene, is sensitive to retinoic acid (RA) treatment, while APL patients harbouring translocations between RARA and the PLZF gene do not respond to RA. We have generated PML-RARA and PLZF-RARA transgenic mice and show here that these fusion proteins play a critical role in leukaemogenesis and in determining responses to RA in APL, because PLZF-RARA transgenic mice develop RA-resistant leukaemia, while PML-RARA mice are responsive to RA treatment. We demonstrate that both PML-RARalpha and PLZF-RARalpha fusion proteins can act as transcriptional repressors and are able to interact with nuclear receptor transcriptional co-repressors, such as SMRT. PLZF-RARalpha, but not PML-RARalpha, can form, via its PLZF moiety, co-repressor complexes which are insensitive to RA. Histone deacetylase inhibitors such as Trichostatin A (TSA), in combination with RA, can overcome the transcriptional repressor activity of PML-RARalpha and PLZF-RARalpha as well as the unresponsiveness of PLZF-RARalpha-expressing leukaemic cells to RA. Thus, our findings unravel a crucial role for transcriptional silencing in APL pathogenesis and resistance to RA in APL.
Acute promyelocytic leukemia (APL) is associated with reciprocal chromosomal translocations involving the retinoic acid receptor ␣ (RAR␣) locus on chromosome 17. In the majority of cases, RAR␣ translocates and fuses with the promyelocytic leukemia (PML) gene located on chromosome 15. The resulting fusion genes encode the two structurally unique PML͞RAR␣ and RAR␣͞PML fusion proteins as well as aberrant PML gene products, the respective pathogenetic roles of which have not been elucidated. We have generated transgenic mice in which the PML͞RAR␣ fusion protein is specifically expressed in the myeloid-promyelocytic lineage. During their first year of life, all the PML͞RAR␣ transgenic mice have an abnormal hematopoiesis that can best be described as a myeloproliferative disorder. Between 12 and 14 months of age, 10% of them develop a form of acute leukemia with a differentiation block at the promyelocytic stage that closely mimics human APL even in its response to retinoic acid. Our results are conclusive in vivo evidence that PML͞RAR␣ plays a crucial role in the pathogenesis of APL.
Acute promyelocytic leukemia (APL) is associated with chromosomal translocations that always involve the RARalpha gene, which variably fuses to one of several distinct loci, including PML or PLZF (X genes). Due to the reciprocity of the translocation, X-RARalpha and RARalpha-X fusion proteins coexist in APL blasts. PLZF-RARalpha transgenic mice (TM) develop leukemia that lacks the differentiation block at the promyelocytic stage that characterizes APL. We generated TM expressing RARalpha-PLZF and PLZF-RARalpha in their promyelocytes. RARalpha-PLZF TM do not develop leukemia. However, PLZF-RARalpha/RARalpha-PLZF double TM develop leukemia with classic APL features. We demonstrate that RARalpha-PLZF can interfere with PLZF transcriptional repression and that this is critical for APL pathogenesis, since leukemias in PLZF(-/-)/PLZF-RARalpha mutants and in PLZF-RARalpha/RARalpha-PLZF TM are indistinguishable. Thus, both products of a cancer-associated translocation are crucial in determining the distinctive features of the disease.
In Drosophila, the visceral mesoderm giving rise to gut musculature is specified by the bagpipe homeobox gene. We have isolated, from both mouse and human, homologues of the bagpipe gene designated Bapx1 and BAPX1, respectively. Bapx1 encodes a predicted protein of 333 amino acids, and has significant regions of homology outside the homeodomain with members of the NK homeobox gene superfamily. Bapx1 maps to the proximal end of chromosome 5 in mouse, near the Msx1 gene. The syntenic region in human corresponds to a chromosomal region containing loci for several skeletal disorders. Bapx1 is first detectable in embryos just prior to axis rotation in lateral plate mesoderm (splanchnic mesoderm) adjacent to the endodermal lining of the prospective gut, and in the most newly formed somites in the region corresponding to the presclerotome, the precursor of the vertebrae. Thus, Bapx1 is one of the earliest developmental markers for the sclerotome portion of the somite and the gut mesentery. Bapx1 continues to be expressed well into organogenesis in lateral plate mesoderm surrounding the mid- and hindgut, and in essentially all cartilaginous condensations which will subsequently undergo endochondral bone formation. The expression pattern of Bapx1 in murine embryos suggests that there are evolutionary conserved mechanisms of visceral mesoderm development across the animal kingdom, and that the mammalian Bapx1 gene may have recently acquired an additional developmental role in skeletal patterning.
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