Breathless, a Drosophila FGF receptor homolog, is required for the onset of tracheal cell migration and tracheole formation.

Breathless, a Drosophila FGF receptor homolog (DFGF-R1), was shown to be essential for the migration of the tracheal cells and the posterior midline glia cells. The temporal requirement for the activity of this receptor was dissected by a dominant-negative construct lacking a functional cytoplasmic tyrosine-kinase domain. Induction of the construct prior to the onset of tracheal or glial cell migration produced phenotypes that were similar to those observed in the corresponding tissues of breathless null mutant embryos. However, this effect is not detected if the dominant-negative receptor is induced after the initiation of tracheal cell migration, indicating that Breathless is required primarily at the onset of the migration process. Induction of the construct after the tracheal branches are completed, blocked the formation of tracheoles, i.e. extension of cellular processes by the terminal tracheal cells, demonstrating that Breathless plays an essential role in this process as well. The requirement for Breathless at the onset of migration and the diversity of processes in which it participates, suggest that the receptor is involved in triggering transcription factors, which may be distinct for each context.

Elucidation of the role of breathless, a Drosophila FGF receptor homolog, in tracheal cell migration.

DFGF-R1 (breathless), a Drosophila FGF receptor homolog, is required for the migration of tracheal cells and the posterior midline glial cells during embryonic development. To define the role of this receptor in cell migration, we have monitored the biological effects of a deregulated receptor containing the extracellular and transmembrane regions of the torso dominant allele and the cytoplasmic domain of DFGF-R1. Ubiquitous expression of the chimeric receptor at the time of tracheal cell migration did not disrupt migration in wild-type embryos. However, induction of the chimeric receptor corrected the tracheal defects of breathless (btl) mutant embryos, allowing the tracheal cells to migrate along their normal tracts. This result indicates that the normal activity of DFGF-R1 in promoting cell migration does not require spatially restricted cues. Late inductions of the chimeric construct, after the normal initiation of tracheal migration, allowed the definition of a broad time window during which the external signals guiding migration persist and the tracheal cells retain the capacity to respond to these cues. Rescue of tracheal migration in btl mutant embryos by the chimeric construct provides a sensitive biological assay for the activity of other Drosophila receptor tyrosine kinases (RTKs). Deregulated receptors containing the cytoplasmic domains of DFGF-R2, DER, torso, and sevenless were all able to partially rescue the migration defects. Consistent with the notion that these RTKs share a common signaling pathway, constructs containing the activated downstream elements Dras1 and Draf were also able to rescue tracheal migration, demonstrating that these two proteins are key players in the DFGF-R1 signaling pathway.

B-lineage cells in mu-transgenic scid mice proliferate in response to IL-7 but fail to show evidence of immunoglobulin light chain gene rearrangement.

The severe combined immunodeficiency (scid) mouse mutation impairs the recombination of Ig and TCR genes. Mice homozygous for this mutation (scid mice) lack pre-B, B, and T lymphocytes. Earlier we introduced a functionally rearranged mu-heavy chain gene into the scid mouse genome and found that this resulted in the development of pre-B cells in the bone marrow of these mice; however, sIgM+ B cells were not detected. We have now investigated the growth properties and rearrangement status of Ig genes in early B-lineage cells arising in mu-transgenic scid mice. We find that the presence of a functional mu-transgene allows pro-B cells from these mice to proliferate in short-term culture with IL-7. Nevertheless, rearrangements of Ig light chain genes are not detected in the bone marrow of such mice. Furthermore, the frequency of rearrangement detected at the endogenous Ig heavy chain locus in scid pro-B and pre-B cells is reduced relative to that in wild-type cells.

Development of B-lineage cells in the bone marrow of scid/scid mice following the introduction of functionally rearranged immunoglobulin transgenes.

Mice homozygous for the mutation scid (scid mice) are severely immunodeficient and generally lack detectable numbers of pre-B, B, and T cells. This condition is believed to result from a defect in the mechanism responsible for rearrangement of immunoglobulin and T-cell receptor genes in developing B and T lymphocytes. To test this hypothesis and evaluate whether scid affects only the process of gene recombination, we introduced functionally rearranged immunoglobulin genes into the scid mouse genome. As scid mice appear to contain early lymphoid cells committed to the B lineage (pro-B cells), we asked whether the introduction of an IgM heavy-chain gene alone (mu-transgenic scid mice) or both IgM heavy- and kappa light-chain genes (mu kappa-transgenic scid mice) would allow further differentiation of scid pro-B cells into pre-B and B cells. We found that normal numbers of pre-B cells appeared in the bone marrow of mu-transgenic scid mice and that both pre-B and B cells appeared in the bone marrow of mu kappa-transgenic scid mice. However, in the latter case, the number of pre-B and B cells was 2- to 3-fold less than in the controls (mu kappa-transgenic scid heterozygotes) and few, if any, B cells were detectable in the peripheral lymphoid tissues. The implications of these results for the above hypothesis are discussed.