The dorsoventral patterning of musca domestica embryos: insights into BMP/ Dpp evolution from the base of the lower cyclorraphan flies

Abstract

Background: In the last few years, accumulated information has indicated that the evolution of an extra-embryonic membrane in dipterans was accompanied by changes in the gene regulatory network controlled by the BMP/Dpp pathway, which is responsible for dorsal patterning in these insects However, only comparative analysis of gene expression levels between distant species with two extra-embryonic membranes, like A.gambiae or C.albipunctata, and D.melanogaster, has been conducted Analysis of gene expression in ancestral species, which evolved closer to the amnioserosa origin, could provide new insights into the evolution of dorsoventral patterning in dipterans.

Results: Here we describe the spatial expression of several key and downstream elements of the Dpp pathway and show the compared patterns of expression between Musca and Drosophila embryos, both dipterans with amniioseros.a Most of the analyzed gene showed a high degree of expression conservation, however, we found several differences in the gene expression pattern of M domestica orthologs for sog and tolloid Bioinformatics analysis of the promoter of both genes indicated that the variations could be related to the gain of several binding sites for the transcriptional factor Dorsal in the M. tld promoter and Snail in the M. sog enhance.r These altered expressions could explain the unclear formation of the pMad gradient in the . domestica embryo, compared to the formation of the gradient in . melanogaste.

Conclusion: Gene expression changes during the dorsal-ventral patterning in insects contribute to the differentiation of extra-embryonic tissues as a consequence of changes in the gene regulatory network controlled by BMP/ Dpp. In this work, in early M.domestica embryos, we identified the expression pattern of several genes members involved in the dorsoventral specification of the embryo. We believe that these data can contribute to understanding the evolution of the BMP/Dpp pathway, the regulation of BMP ligands, and the formation of a Dpp gradient in higher cyclorraphan flies.