Engrailed-1 misexpression in chick embryos prevents apical ridge formation but preserves segregation of dorsal and ventral ectodermal compartments.

Using lineage tracers, we recently showed dorsal and ventral ectodermal compartments along the sides of the body in chick embryos. The compartments are formed both in presumptive limb-forming regions where they position the apical ridge and also in presumptive interlimb (flank). Here we show, using a novel technique combining fate mapping and in situ hybridisation, that the ventral compartment coincides with the Engrailed-1 (En-1) domain of expression. This coincidence suggests that En-1 could maintain the ventral compartment and be necessary for apical ridge formation. To test this hypothesis, we ectopically expressed En-1 via retroviral transfer and then examined limb development and cell lineage restriction in the ectoderm. En-1 misexpression can completely prevent formation of both normal limbs and ectopic limbs induced in the flank by application of FGF-2. In both cases, there are no morphological signs of apical ectodermal ridge formation and expression of ridge-associated genes is undetectable. In striking contrast, the lineage restriction between dorsal and ventral ectoderm is not altered. Therefore, En-1 is involved in the regulation of ridge formation but not compartment maintenance.

Epithelial cell movements and interactions in limb, neural crest and vasculature.

Formation of the thickened apical ectodermal ridge of developing vertebrate limbs appears to be a complex process. Direct connections to molecular controls of cell migratory machinery have been shown for first time in neural crest migration. New unsuspected roles are emerging for ephrin ligand/Eph receptor signalling in vascular morphogenesis.

Tbx genes and limb identity in chick embryo development.

Tbx-2, Tbx-3, Tbx-4 and Tbx-5 chick genes have been isolated and, like the mouse homologues, are expressed in the limb regions. Tbx-2 and Tbx-3 are expressed in anterior and posterior domains in wings and legs, as well as throughout the flank. Of particular interest, however, are Tbx-5, which is expressed in wing and flank but not leg, and Tbx-4, which is expressed very strongly in leg but not wing. Grafts of leg tissue to wing and wing tissue to leg give rise to toe-like or wing-like digits in wing and leg respectively. Expression of Tbx-4 is stable when leg tissue is grafted to wing, and Tbx-5 expression is stable when wing tissue is grafted to leg. Induction of either extra wings or legs from the flank by applying FGF-2 in different positions alters the expression of Tbx-4 and Tbx-5 in such a way that suggests that the amount of Tbx-4 that is expressed in the limb determines the type that will form. The ectopic limb always displays a limb-like Tbx-3 expression. Thus Tbx-4 and Tbx-5 are strong candidates for encoding 'wingness' and 'legness'.

Dorso-ventral ectodermal compartments and origin of apical ectodermal ridge in developing chick limb.

We wish to understand how limbs are positioned with respect to the dorso-ventral axis of the body in vertebrate embryos, and how different regions of limb bud ectoderm, i.e. dorsal ectoderm, apical ridge and ventral ectoderm, originate. Signals from dorsal and ventral ectoderm control dorso-ventral patterning while the apical ectodermal ridge (AER) controls bud outgrowth and patterning along the proximo-distal axis. We show, using cell-fate tracers, the existence of two distinct ectodermal compartments, dorsal versus ventral, in both presumptive limb and flank of early chick embryos. This organisation of limb ectoderm is the first direct evidence, in vertebrates, of compartments in non-neural ectoderm. Since the apical ridge appears to be confined to this compartment boundary, this positions the limb. The mesoderm, unlike the ectoderm, does not contain two separate dorsal and ventral cell lineages, suggesting that dorsal and ventral ectoderm compartments may be important to ensure appropriate control of mesodermal cell fate. Surprisingly, we also show that cells which form the apical ridge are initially scattered in a wide region of early ectoderm and that both dorsal and ventral ectoderm cells contribute to the apical ridge, intermingling to some extent within it.

A truncated RAR alpha co-operates with the v-erbB oncogene to transform early haematopoietic progenitors in vitro and in vivo.

We have shown recently that a retrovirus vector expressing a natural mutant form of the PML-RAR alpha protein characteristic of human acute promyelocytic leukaemia can transform early chicken hematopoietic progenitors (Altabef et al., 1996). Neither truncated PML nor truncated RAR alpha alone could induce transformation which suggest that the two domains should cooperate for the oncogenicity of the fusion product. To further investigate the mechanisms of this co-operation, we have tested whether a truncated RAR alpha could cooperate with the v-erbB oncogene. This oncogene has previously been shown to co-operate with the rearranged thyroid hormone receptor, v-erbA, to transform erythrocytic progenitors. We show that v-erbB and a truncated RAR alpha co-operate when expressed simultaneously as independent products to transform very early chicken haematopoietic cells close to pluripotent stage. In addition, we show that v-erbB alters transcriptional abilities of RAR alpha by both enhancing its effects on RARE and reducing those on AP-1. Therefore, RAR alpha is able to co-operate with different kinds of proteins to induce transformation of early haematopoietic cells. This strongly suggests that RAR alpha are involved in the differentiation commitment of early haematopoietic progenitors during the normal process of haematopoietic differentiation. These data bring new insights in the mechanisms of oncogenic transformation by rearranged RAR alpha.

A retrovirus carrying the promyelocyte-retinoic acid receptor PML-RARalpha fusion gene transforms haematopoietic progenitors in vitro and induces acute leukaemias.

The promyelocyte (PML)-retinoic acid receptor alpha (RARalpha) fusion gene results from a t(15;17) chromosome translocation in acute promyelocytic leukaemia. We have analysed the oncogenic potential of the human fusion PML-RARalpha product in chicken using retrovirus vectors. We show that PML-RARalpha transforms very early haematopoietic progenitor cells in vitro and induces acute leukaemias. Neither PML nor RARalpha domains alone achieve such a transformation. The PML-RARalpha viruses recovered from the transformed cells carry two point mutations in the PML domain, one of which alters both the pattern of intracellular localization of the fusion protein and its functional interference with AP-1, thus defining an essential domain in PML for oncogenic transformation.

v-erbA stimulates quail myoblast differentiation in a T3 independent, cell-specific manner.

The v-erbA oncoprotein represents a mutated version of a thyroid hormone receptor, responsible for the induction of a differentiation arrest in chicken erythroid cells. We have studied the influence of v-erbA on proliferation and differentiation of avian myoblasts. Secondary quail myoblast cultures were infected either with an avian retrovirus carrying the v-erbA oncogene in association with the neomycin resistance gene, or with a control deleted v-erbA/neoR alpha retrovirus. We report here that v-erbA expression led to an increase in myoblast proliferation and to a surprising stimulation of quail myoblast terminal differentiation. In addition, these effects occurred in the presence or absence of T3, and v-erbA did not suppress T3 influence on myoblasts. Transient transfection assays demonstrated that, in contrast to its action in HeLa cells, v-erbA was unable to repress the transcriptional activation of a TRE-CAT reporter gene by liganded c-erbA alpha receptors in quail myoblasts. We also observed that the AP-1/c-erbA/v-erbA interactions are not functional in quail myoblasts. These data suggest that, in these cells, v-erbA action does not interfere with T3 induced mechanisms. They also demonstrate a cell specificity for the v-erbA pathway. Lastly, expression of c-erbA/v-erbA chimeric proteins and of the S61G v-erbA mutant indicates that the DNA binding domain of v-erbA, and more specifically serine 61, is directly involved in the enhancement of myoblast differentiation by the oncoprotein.