Role of BMP and FGF signaling during limb development
Division Of Basic Sciences - Nci
Investigators
Linked publications, trials & patents
Abstract
In previous work, we produced genetic evidence for a novel model in which the surface ectoderm must receive a BMP signal, resulting in down regulation of Fgfs which in turn induces apoptosis of the underlying mesenchyme. Thus we demonstrated that BMPs control programmed cell death indirectly, by regulating FGF signaling. However, it is important to emphasize that this insight does not exclude a direct role for BMP signaling in controlling cell death in the developing limb. Therefore, we extended these studies by studying the role of BMP and FGF signaling in various aspects of limb development using mouse lines that express Cre in specific region of the developing limb. For example the only way to test the hypothesis that BMPs act as direct effectors of cell death is to inactivate BMPs receptors only in the lineage that undergoes cells death, without affecting FGF expression in nearby cells. We have achieved this using new Cre lines that allow Cre-mediated gene inactivation in these lineages. With these lines we have determined that BMPs are direct effectors of cell death (Dev Biol. 411: 266-76). In current work, we showed that a gradient of Meis homeodomain transcription factors along the mouse limb bud proximo-distal (PD) axis antiparallel to and shaped by the inhibitory action of distal FGF signals. Elimination of Meis results in premature limb distalization and proximalization of PD segmental borders, and phocomelia. Our results show that Meis transcription factors interpret FGF signaling to convey positional information along the limb bud PD axis. These findings establish a new model for the generation of PD identities in the vertebrate limb and provide a molecular basis for the interpretation of FGF signal gradients during axial patterning (Sci Adv, 2020, PMID: 32537491) . In ongoing work, we are defining the role of distal FGF signals in generating the pattern and differentiation of the pelvis in the hindlimb. We had previously demonstrated that these FGF signals are downstream of the BMP receptor, 1a (Development, 2007, PMID: 17537800) . We are now using sophisticated genetics and cutting-edge imagery of gene expression to define which FGFs are responsible for forming this most proximal element and initiating limb formation.
View original record on NIH RePORTER →