E2a/Pbx1 induces the rapid proliferation of stem cell factor-dependent murine pro-T cells that cause acute T-lymphoid or myeloid leukemias in mice

Oncoprotein E2a/Pbx1 is produced by the t(1;19) chromosomal translocation of human pre-B acute lymphoblastic leukemia. E2a/Pbx1 blocks differentiation of primary myeloid progenitors but, paradoxically, induces apoptosis in established pre-B-cell lines, and no transforming function of E2a/Pbx1 has been reported in cultured lymphoid progenitors. Here, we demonstrate that E2a/Pbx1 induces immortal proliferation of stem cell factor (SCF)-dependent pro-T thymocytes by a mechanism dependent upon both its transactivation and DNA-binding functions. E2a-Pbx1 cooperated with cytokines or activated signaling oncoproteins to induce cell division, as inactivation of conditional E2a/Pbx1 in either factor-dependent pro-T cells or pro-T cells made factor independent by expression of Bcr/Abl resulted in pro-T-cell quiescence, while reactivation of E2a/Pbx1 restored cell division. Infusion of E2a/Pbx1 pro-T cells in mice caused T lymphoblastic leukemia and, unexpectedly, acute myeloid leukemia. The acute lymphoblastic leukemia did not evidence further maturation, suggesting that E2a/Pbx1 establishes an early block in pro-T-cell development that cannot be overcome by marrow or thymic microenvironments. In an E2a/Pbx1 pro-T thymocyte clone that induced only pro-T acute lymphoblastic leukemia, coexpression of Bcr/Abl expanded its leukemic phenotype to include acute myeloid leukemia, suggesting that unique functions of cooperating signaling oncoproteins can influence the lymphoid versus myeloid character of E2a/Pbx1 leukemia and may cooperate with E2a/Pbx1 to dictate the pre-B-cell phenotype of human leukemia containing t(1;19).     

Meis proteins are major in vivo DNA binding partners for wild-type but not chimeric Pbx proteins.

The Pbx1 and Meis1 proto-oncogenes code for divergent homeodomain proteins that are targets for oncogenic mutations in human and murine leukemias, respectively, and implicated by genetic analyses to functionally collaborate with Hox proteins during embryonic development and/or oncogenesis. Although Pbx proteins have been shown to dimerize with Hox proteins and modulate their DNA binding properties in vitro, the biochemical compositions of endogenous Pbx-containing complexes have not been determined. In the present study, we demonstrate that Pbx and Meis proteins form abundant complexes that comprise a major Pbx-containing DNA binding activity in nuclear extracts of cultured cells and mouse embryos. Pbx1 and Meis1 dimerize in solution and cooperatively bind bipartite DNA sequences consisting of directly adjacent Pbx and Meis half sites. Pbx1-Meis1 heterodimers display distinctive DNA binding specificities and cross-bind to a subset of Pbx-Hox sites, including those previously implicated as response elements for the execution of Pbx-dependent Hox programs in vivo. Chimeric oncoprotein E2a-Pbx1 is unable to bind DNA with Meis1, due to the deletion of amino-terminal Pbx1 sequences following fusion with E2a. We conclude that Meis proteins are preferred in vivo DNA binding partners for wild-type Pbx1, a relationship that is circumvented by its oncogenic counterpart E2a-Pbx1.     

The pentapeptide motif of Hox proteins is required for cooperative DNA binding with Pbx1, physically contacts Pbx1, and enhances DNA binding by Pbx1.

The vertebrate Hox genes, which represent a subset of all homeobox genes, encode proteins that regulate anterior-posterior positional identity during embryogenesis and are cognates of the Drosophila homeodomain proteins encoded by genes composing the homeotic complex (HOM-C). Recently, we demonstrated that multiple Hox proteins bind DNA cooperatively with both Pbx1 and its oncogenic derivative, E2A-Pbx1. Here, we show that the highly conserved pentapeptide motif F/Y-P-W-M-R/K, which occurs in numerous Hox proteins and is positioned 8 to 50 amino acids N terminal to the homeodomain, is essential for cooperative DNA binding with Pbx1 and E2A-Pbx1. Point mutational analysis demonstrated that the tryptophan and methionine residues within the core of this motif were critical for cooperative DNA binding. A peptide containing the wild-type pentapeptide sequence, but not one in which phenylalanine was substituted for tryptophan, blocked the ability of Hox proteins to bind cooperatively with Pbx1 or E2A-Pbx1, suggesting that the pentapeptide itself provides at least one surface through which Hox proteins bind Pbx1. Furthermore, the same peptide, but not the mutant peptide, stimulated DNA binding by Pbx1, suggesting that interaction of Hox proteins with Pbx1 through the pentapeptide motif raises the DNA-binding ability of Pbx1.     

Requirement for Pbx1 in skeletal patterning and programming chondrocyte proliferation and differentiation

Pbx1 and a subset of homeodomain proteins collaboratively bind DNA as higher-order molecular complexes with unknown consequences for mammalian development. Pbx1 contributions were investigated through characterization of Pbx1-deficient mice. Pbx1 mutants died at embryonic day 15/16 with severe hypoplasia or aplasia of multiple organs and widespread patterning defects of the axial and appendicular skeleton. An obligatory role for Pbx1 in limb axis patterning was apparent from malformations of proximal skeletal elements, but distal structures were unaffected. In addition to multiple rib and vertebral malformations, neural crest cell-derived skeletal structures of the second branchial arch were morphologically transformed into elements reminiscent of first arch-derived cartilages. Although the skeletal malformations did not phenocopy single or compound Hox gene defects, they were restricted to domains specified by Hox proteins bearing Pbx dimerization motifs and unaccompanied by alterations in Hox gene expression. In affected domains of limbs and ribs, chondrocyte proliferation was markedly diminished and there was a notable increase of hypertrophic chondrocytes, accompanied by premature ossification of bone. The pattern of expression of genes known to regulate chondrocyte differentiation was not perturbed in Pbx1-deficient cartilage at early days of embryonic skeletogenesis, however precocious expression of Col1a1, a marker of bone formation, was found. These studies demonstrate a role for Pbx1 in multiple developmental programs and reveal a novel function in co-ordinating the extent and/or timing of proliferation with terminal differentiation. This impacts on the rate of endochondral ossification and bone formation and suggests a mechanistic basis for most of the observed skeletal malformations.     

Segmental expression of Hoxb2 in r4 requires two separate sites that integrate cooperative interactions between Prep1, Pbx and Hox proteins

Direct auto- and cross-regulatory interactions between Hox genes serve to establish and maintain segmentally restricted patterns in the developing hindbrain. Rhombomere r4-specific expression of both Hoxb1 and Hoxb2 depends upon bipartite cis Hox response elements for the group 1 paralogous proteins, Hoxal and Hoxbl. The DNA-binding ability and selectivity of these proteins depend upon the formation of specific heterodimeric complexes with members of the PBC homeodomain protein family (Pbx genes). The r4 enhancers from Hoxb1 and Hoxb2 have the same activity, but differ with respect to the number and organisation of bipartite Pbx/Hox (PH) sites required, suggesting the intervention of other components/sequences. We report here that another family of homeodomain proteins (TALE, Three-Amino acids-Loop-Extension: Prep1, Meis, HTH), capable of dimerizing with Pbx/EXD, is involved in the mechanisms of r4-restricted expression. We show that: (1) the r4-specific Hoxb1 and Hoxb2 enhancers are complex elements containing separate PH and Prep/Meis (PM) sites; (2) the PM site of the Hoxb2, but not Hoxb1, enhancer is essential in vivo for r4 expression and also influences other sites of expression; (3) both PM and PH sites are required for in vitro binding of Prepl-Pbx and formation and binding of a ternary Hoxbl-Pbxla (or 1b)-Prepl complex. (4) A similar ternary association forms in nuclear extracts from embryonal P19 cells, but only upon retinoic acid induction. This requires synthesis of Hoxbl and also contains Pbx with either Prepl or Meisl. Together these findings highlight the fact that PM sites are found in close proximity to bipartite PH motifs in several Hox responsive elements shown to be important in vivo and that such sites play an essential role in potentiating regulatory activity in combination with the PH motifs.     

Engrailed and Hox homeodomain proteins contain a related Pbx interaction motif that recognizes a common structure present in Pbx.

Hox gene products have the ability to interact with either extradenticle or pbx gene products to bind cooperatively to DNA. The region in Hox proteins that is required for this interaction is located N-terminal of the homeodomain and contains a highly conserved hexapeptide. We now show that the engrailed gene products also contain a Pbx interaction motif positioned within a previously conserved region, the EH2 domain. The EH2 domain is located N-terminal of the homeodomain. Two tryptophan residues present in the Drosophila and murine Engrailed EH2 domain are required for cooperativity with extradenticle and Pbx, respectively. A second conserved domain, EH3, is required as well for cooperativity with Pbx, since deletions or an insertion in this region reduce cooperative DNA binding. Peptides containing the Pbx interaction motif of either Engrailed or Hox are capable of destabilizing Engrailed-Pbx and Hox-Pbx cooperative DNA binding. These data indicate that the Pbx interaction motifs present in Hox and engrailed gene products recognize a common structure present in the Pbx family of homeodomain proteins.     

Structural determinants within Pbx1 that mediate cooperative DNA binding with pentapeptide-containing Hox proteins: proposal for a model of a Pbx1-Hox-DNA complex.

Genetic studies have identified a family of divergent homeodomain proteins, including the human protooncoprotein Pbx1 and its drosophila homolog extradenticle (Exd), which function as cofactors with a subset of Hox and HOM-C proteins, and are essential for specific target gene expression. Pbx1/Exd binds DNA elements cooperatively with a large subset of Hox/HOM-C proteins containing a conserved pentapeptide motif, usually YPWMR, located just N terminally to their homeodomains. The pentapeptide is essential for cooperative DNA binding with Pbx1. In this study, we identify structural determinants of Pbx1 that are required for cooperative DNA binding with the pentapeptide-containing Hox protein HoxA5. We demonstrate that the homeodomain of Pbx1 contains a surface that binds the pentapeptide motif and that the Pbx1 homeodomain is sufficient for cooperative DNA binding with a Hox protein. A sequence immediately C terminal to the Pbx1 homeodomain, which is highly conserved in Pbx2 and Pbx3 and predicted to form an alpha-helix, enhances monomeric DNA binding by Pbx1 and also contributes to maximal cooperativity with Hox proteins. Binding studies with chimeric HoxA5-Pbx1 fusion proteins suggest that the homeodomains of Pbx1 and HoxA5 are docked on the representative element, TTGATTGAT, in tandem, with Pbx1 recognizing the 5' TTGAT core motif and the Hox protein recognizing the 3' TGAT core. The proposed binding orientation permits Hox proteins to exhibit further binding specificity on the basis of the identity of the four residues 3' to their core binding motif.