Multiple forces contribute to cell sheet morphogenesis for dorsal closure in Drosophila.

The molecular and cellular bases of cell shape change and movement during morphogenesis and wound healing are of intense interest and are only beginning to be understood. Here, we investigate the forces responsible for morphogenesis during dorsal closure with three approaches. First, we use real-time and time-lapsed laser confocal microscopy to follow actin dynamics and document cell shape changes and tissue movements in living, unperturbed embryos. We label cells with a ubiquitously expressed transgene that encodes GFP fused to an autonomously folding actin binding fragment from fly moesin. Second, we use a biomechanical approach to examine the distribution of stiffness/tension during dorsal closure by following the response of the various tissues to cutting by an ultraviolet laser. We tested our previous model (Young, P.E., A.M. Richman, A.S. Ketchum, and D.P. Kiehart. 1993. Genes Dev. 7:29-41) that the leading edge of the lateral epidermis is a contractile purse-string that provides force for dorsal closure. We show that this structure is under tension and behaves as a supracellular purse-string, however, we provide evidence that it alone cannot account for the forces responsible for dorsal closure. In addition, we show that there is isotropic stiffness/tension in the amnioserosa and anisotropic stiffness/tension in the lateral epidermis. Tension in the amnioserosa may contribute force for dorsal closure, but tension in the lateral epidermis opposes it. Third, we examine the role of various tissues in dorsal closure by repeated ablation of cells in the amnioserosa and the leading edge of the lateral epidermis. Our data provide strong evidence that both tissues appear to contribute to normal dorsal closure in living embryos, but surprisingly, neither is absolutely required for dorsal closure. Finally, we establish that the Drosophila epidermis rapidly and reproducibly heals from both mechanical and ultraviolet laser wounds, even those delivered repeatedly. During healing, actin is rapidly recruited to the margins of the wound and a newly formed, supracellular purse-string contracts during wound healing. This result establishes the Drosophila embryo as an excellent system for the investigation of wound healing. Moreover, our observations demonstrate that wound healing in this insect epidermal system parallel wound healing in vertebrate tissues in situ and vertebrate cells in culture (for review see Kiehart, D.P. 1999. Curr. Biol. 9:R602-R605).

Isolation and characterization of Leishmania mutants defective in glycosomal protein import.

Kinetoplastid parasites contain a unique microbody organelle called the glycosome. Several important metabolic pathways found in the cytoplasm of higher eukaryotes are compartmentalized within the glycosome in these pathogens. This fundamental difference between the host and parasite has led to consideration of the glycosome as a potential chemotherapeutic target. The genetic basis of glycosome biogenesis is therefore of great interest. This report describes the isolation of multiple Leishmania mutant cell lines defective in glycosomal protein import, and the detailed characterization of three such lines. The mutants examined partially mislocalize a subset of glycosomal proteins to the cytosol yet retain wild-type numbers of glycosomes. One of the mutants has a mutation in the previously identified LdPEX2 (GIM1) gene. The other two mutants are demonstrated to contain cell-specific lesions in one or more genes distinct from PEX2. The identification of multiple genetically distinct mutants with defects in glycosome import provides an important genetic tool to facilitate the identification of genes involved in glycosome biogenesis.

Functional identification of a Leishmania gene related to the peroxin 2 gene reveals common ancestry of glycosomes and peroxisomes.

Glycosomes are membrane-bounded microbody organelles that compartmentalize glycolysis as well as other important metabolic processes in trypanosomatids. The compartmentalization of these enzymatic reactions is hypothesized to play a crucial role in parasite physiology. Although the metabolic role of glycosomes differs substantially from that of the peroxisomes that are found in other eukaryotes, similarities in signals targeting proteins to these organelles suggest that glycosomes and peroxisomes may have evolved from a common ancestor. To examine this hypothesis, as well as gain insights into the function of the glycosome, we used a positive genetic selection procedure to isolate the first Leishmania mutant (gim1-1 [glycosome import] mutant) with a defect in the import of glycosomal proteins. The mutant retains glycosomes but mislocalizes a subset glycosomal proteins to the cytoplasm. Unexpectedly, the gim1-1 mutant lacks lipid bodies, suggesting a heretofore unknown role of the glycosome. We used genetic approaches to identify a gene, GIM1, that is able to restore import and lipid bodies. A nonsense mutation was found in one allele of this gene in the mutant line. The predicted Gim1 protein is related the peroxin 2 family of integral membrane proteins, which are required for peroxisome biogenesis. The similarities in sequence and function provide strong support for the common origin model of glycosomes and peroxisomes. The novel phenotype of gim1-1 and distinctive role of Leishmania glycosomes suggest that future studies of this system will provide a new perspective on microbody biogenesis and function.

Modifications in myotendinous junction surface morphology in dystrophin-deficient mouse muscle.

Single muscle fibers from mdx mouse muscle, which is deficient in dystrophin, and control mouse muscle, containing dystrophin, were compared by scanning electron microscopy. In particular, comparisons were made of the surface morphology at myotendinous junctions and costameres, sites at the muscle cell surface that are enriched in dystrophin and where force is transmitted across the cell membrane. Muscle fibers from 4- and 6-week-old controls display nearly uniform surface morphology characterized by numerous digit-like processes at the myotendinous junction and nonjunctional surface membrane possessing distinct grooves at sites corresponding to underlying costameres. Mdx fibers at this stage showed blunted myotendinous junctions with few digit-like processes, infrequent indistinct costameric markings, and holes in the cell membrane. Cells from peak regenerating mdx muscle (6 weeks) showed surface morphology similar to 4-week mdx fibers, although the proportion of fibers displaying extensive structural defects was reduced at 6 weeks. Completely regenerated mdx fibers (23 weeks) were indistinguishable from fibers of 6-week-old mdx mice. In control mice, only approximately 6% of the fibers examined from 4- or 6-week-old mice showed any of the structural defects characteristic of the majority of mdx fibers. However, fibers from 23-week-old control mice displayed an increased frequency of cells with poorly defined junctional processes and surface striations. These findings indicate that the fibers displaying extensive disruption of surface features, which are most commonly observed in 4-week mdx mice at peak necrosis, are necrotic fibers. Specific defects, such as the reduction in myotendinous junction folding, loss of costameres, and increased occurrence of membrane holes, are observed in the majority of mdx fibers at all ages. Thus, these defects are more directly attributable to dystrophin's absence because their frequency of occurrence is independent of the stage of necrosis and regeneration.

The effects of 20-hydroxyecdysone on the metabolic labeling of membrane proteins in Drosophila imaginal discs.

20-Hydroxyecdysone induces evagination of imaginal discs of Drosophila melanogaster cultured in vitro. The possible involvement of cell-surface proteins in this process has prompted us to study the synthesis of membrane proteins in imaginal discs. A procedure is reported for the isolation of membrane vesicle fractions from discs that are enriched for the plasma membrane enzyme, Na+/K+-ATPase, and that label with the surface-labeling reagent [125I]iodosulfanilic acid. 20-Hydroxyecdysone alters the pattern of [35S]methionine incorporation into polypeptides in these membrane vesicle fractions. Increased and decreased incorporation as well as changes in migration on two-dimensional gels of specific polypeptides are caused by the hormone. These changes parallel in time the onset and the continuation of evagination.