Vestigial Is Required during Late-Stage Muscle Differentiation in Drosophila melanogaster Embryos

The somatic muscles of Drosophila develop in a complex pattern that is repeated in each embryonic hemi-segment. During early development, progenitor cells fuse to form a syncytial muscle, which further differentiates via expression of muscle-specific factors that induce specific responses to external signals to regulate late-stage processes such as migration and attachment. Initial communication between somatic muscles and the epidermal tendon cells is critical for both of these processes. However, later establishment of attachments between longitudinal muscles at the segmental borders is largely independent of the muscle–epidermal attachment signals, and relatively little is known about how this event is regulated. Using a combination of null mutations and a truncated version of Sd that binds Vg but not DNA, we show that Vestigial (Vg) is required in ventral longitudinal muscles to induce formation of stable intermuscular attachments. In several muscles, this activity may be independent of Sd. Furthermore, the cell-specific differentiation events induced by Vg in two cells fated to form attachments are coordinated by Drosophila epidermal growth factor signaling. Thus, Vg is a key factor to induce specific changes in ventral longitudinal muscles 1–4 identity and is required for these cells to be competent to form stable intermuscular attachments with each other.     

Expression and functional analysis of a novel Fusion Competent Myoblast specific GAL4 driver

In the Drosophila embryo, body wall muscles are formed by the fusion of two cell types, Founder Cells (FCs) and Fusion Competent Myoblasts (FCMs). Using an enhancer derived from the Dmef2 gene ([C/D]( *)), we report the first GAL4 driver specifically expressed in FCMs. We have determined that this GAL4 driver causes expression in a subset of FCMs and, upon fusion, in developing myotubes from stage 14 onwards. In addition, we have shown that using this Dmef2-5x[C/D]( *)-GAL4 driver to express dominant negative Rac in only FCMs causes a partial fusion block. This novel GAL4 driver will provide a useful reagent to study Drosophila myoblast fusion and muscle differentiation.     

A novel Drosophila, mef2-regulated muscle gene isolated in a subtractive hybridization-based molecular screen using small amounts of zygotic mutant RNA

It is unknown how the general patterning mechanisms that subdivide the mesoderm initiate different pathways of cell differentiation. One route to understanding these events is to isolate and analyse genes specifically expressed early in this differentiation process. I have therefore undertaken a novel molecular screen in Drosophila in a systematic search for such genes. The approach utilised subtractive hybridisation coupled to directional cDNA library construction. Libraries were made from as little as 20 microg total RNA isolated from hand-picked embryos of defined stage of development and genotype. In a one-step procedure, the subtraction was 6.5- to 7.25-h wild-type embryos minus 6.5- to 7.25-h twist (twi) zygotic mutant embryos. A two-step procedure in which maternally expressed sequences were subtracted from each of these cDNA libraries, before subtracting twi from wild-type, increased the subtraction efficiency. It resulted in a cDNA population enriched more than 100-fold for mesodermal cDNAs. This was screened by determination of the embryonic expression pattern of each clone in a high throughput procedure and then DNA sequencing. The method, which is comprehensive and does not discriminate against rarer cDNAs, is generally applicable and calculations show that it would work for just 10 embryos. Analysis of one clone, Dmeso18E, that encodes a putative nuclear protein and fulfils the screen's aims is described. It is novel and its expression is mesoderm-specific, twi-dependent, and early during somatic, visceral, and heart muscle differentiation. Two pivotal regulators of mesoderm development and gene expression are Dmef2 and tinman (tin). Analysis of Dmeso18E expression revealed new aspects to their roles: there are effects of Dmef2 on developing muscle much earlier than hitherto believed, and there is tin-independent gene expression in, and invagination of, prospective midgut visceral muscle cells. Dmeso18E expression is regulated by Dmef2, although some expression is Dmef2-independent. The tin-independent and Dmef2-independent expression of Dmeso18E indicates that it either occupies a link between twi and genes like tin and Dmef2 or it lies in a parallel pathway of gene activation.