Teresa R. Strecker scite author profile

In Drosophila, five "terminal" polarity genes must be active in females in order for them to produce embryos with normal anterior and posterior ends. Hypoactivity mutations in one such gene, torso, result in the loss of the most posterior domain of fushi tarazu expression and the terminal cuticular structures. In contrast, a torso hyperactivity mutation causes the loss of central fushi tarazu expression and central cuticular structures. Cytoplasmic leakage, transplantation, and temperature-shift experiments suggest that the latter effect is caused by abnormal persistence of the torso product in the central region of the embryo during early development. Thus, the amount and timing of torso activity is key to distinguishing the central and terminal regions of the embryo. Mutations in the tailless terminal gene act as dominant maternal suppressors of the hyperactive torso allele, indicating that the torso product acts through, or in concert with, the tailless product.

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The zygotic mutant tailless affects the anterior and posterior ectodermal regions of the Drosophila embryo

Strecker

Kongsuwan

Lengyel

et al. 1986

Developmental Biology

101

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Peripheral nerves do not play a trophic role in limb skeletal morphogenesis

Strecker

Stephens

1983

Teratology

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Research was undertaken to test the hypothesis that thalidomide-induced limb defects resulted from damage to the neural crest or peripheral nerves and that normal limb development depends upon either the quality (level specific) or quantity of peripheral nerves. Barriers which were placed into early chick embryos to block brachial plexus-level neural crest cells from reaching the limb resulted in normal limb skeletons. These data agree with previous work in suggesting that skeletal morphology is independent of innervation.

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Permeabilization, Staining and Culture of Living Drosophila Embryos

Strecker

McGhee

Shih

et al. 1994

Biotechnic & Histochemistry

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The organic solvent octane has been used routinely to permeabilize the hydrophobic vitelline membrane surrounding the Drosophila embryo, thereby allowing the movement of small molecules into the egg. We present evidence that hexane is a more effective permeabilizing agent than octane and compare the effects of these solvents on uniformity of permeabilization and embryonic viability. The ability of each solvent to make the embryo accessible to a range of biological stains was compared. The effect of octane versus hexane permeabilization on subsequent embryonic viability was measured at seven different stages during early embryogenesis. We found that although hexane is a superior solvent for permeabilizing the vitelline membrane, it decreases the viability of embryos exposed between 0 and 3 hr of age. Older embryos treated with either hexane or octane are usually viable. We also showed that molecules with a molecular mass of 984 Daltons or more did not diffuse into the embryo following treatment with either hexane or octane. Results presented here challenge a phase-partition model that has been proposed previously to explain the molecular basis of permeabilization of the Drosophila egg. An alternative model is described as well as an optimized protocol for permeabilizing and staining Drosophila embryos at any stage during early embryogenesis while maintaining viability for subsequent culture.

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