Autocatalytic ftz activation and metameric instability induced by ectopic ftz expression

Inappropriate expression of the Drosophila pair-rule gene, fushi tarazu (ftz), causes cuticular pattern deletions apparently complementary to those in ftz larvae. We show that the two patterns actually originate similarly, in both cases affecting the even-numbered parasegmental boundaries. The reciprocal cuticular patterns derive from differing patterns of selector gene expression (homoeotic transformations). The primary effect of ectopic ftz activity is to broaden ftz domains by autocatalytic activation of endogenous ftz expression in an additional anterior cell. This activates engrailed (en) and represses wingless (wg) expression, consistent with their proposed combinatorial control by ftz (and other pair-rule genes) to define parasegmental primordia. We propose that the anterior margin of each ftz stripe is normally defined by the posterior even-skipped (eve) boundary.     

Craniofacial abnormalities induced by ectopic expression of the homeobox gene Hox-1.1 in transgenic mice

Hox-1.1 is a murine homeobox-containing gene expressed in a time- and cell-specific manner during embryogenesis. We have generated transgenic mice that ectopically express Hox-1.1 from the chicken beta-actin promoter. In these mice Hox-1.1 expression was changed to an almost ubiquitous pattern. Ectopic expression of Hox-1.1 leads to death of the transgenic animals shortly after birth and is associated with multiple craniofacial anomalies, such as cleft palate, open eyes at birth, and nonfused pinnae. This phenotype is similar to the effects seen after systemic administration of retinoic acid during gestation. This suggests that retinoic acid embryopathy and the specific developmental defects caused by ectopic expression of a potential developmental control gene share a common pathogenic mechanism.     

hairy gene function in the Drosophila eye: normal expression is dispensable but ectopic expression alters cell fates.

The regulatory gene hairy is expressed and required during early embryogenesis to control segmentation gene expression properly and during larval and pupal development to control the pattern of certain adult sensory structures. We have found the hairy protein to be expressed transiently during two stages of eye imaginal disc development, including all cells immediately anterior to the morphogenetic furrow that traverses the developing eye disc, and again in the presumptive R7 photoreceptor cells of the developing ommatidia. This pattern is conserved in a significantly diverged Drosophila species. We show that, surprisingly, ommatidia formed by homozygous hairy- mutant clones are apparently normal, indicating that hairy function in the eye is dispensable. However, we do find that ectopic expression of hairy causes numerous structural abnormalities and the alteration of cell fates. Thus, proper regulation of hairy is still essential for normal eye development. We suggest that the loss of hairy function may be compensated by other regulatory proteins, as has been observed previously for several structurally and functionally related genes involved in sensory organ development. The effects of ectopic hairy expression may result from interactions with proneural genes involved in the development of the eye and other sensory organs.     

Low-level ectopic expression of Fushi tarazu in Drosophila melanogaster results in ftz(Ual/Rpl)-like phenotypes and rescues ftz phenotypes

The protein encoded by the Drosophila pair-rule gene fushi tarazu (ftz) is required for the formation of the even-numbered parasegments. Here we analyze the phenotypes of ectopic expression of FTZ and FTZ protein deletions from the Tubulin 1 (Tub1) promoter. Fusion of ftz to the Tub1 promoter resulted in low-level ectopic expression of FTZ relative to FTZ expressed from the endogenous ftz gene. The effects of ectopic expression of four FTZ proteins, FTZ^1–413 (full length wild-type FTZ), FTZ^Δ257–316 (a complete deletion of the HD), FTZ^Δ101–150 (a deletion that includes the major FTZ-F1 binding site) and FTZ^Δ151–209 were determined. Ectopic expression of FTZ^1–413, FTZ^Δ257–316 and FTZ^Δ101–151 did not result in an anti-ftz phenotype; however, ectopic expression of FTZ^1–413, and FTZ^Δ257–316 did result in a ftz^Ual/Rpl-like phenotype. In addition, low-level ectopic expression of FTZ^1–413 and FTZ^Δ257–316 rescued ftz phenotypes. This was an important observation because the even-numbered parasegment pattern of FTZ expression is considered important for normal segmentation. Therefore, the rescue of ftz phenotypes by low-level FTZ expression in all cells of the embryo suggests that the even-numbered parasegment expression pattern of FTZ is not the sole factor restricting FTZ action. Low-level ectopic expression of FTZ^Δ151–209 resulted in the anti-ftz phenotype and rescued hypomorphic ftz-f1 phenotypes indicating that FTZ^Δ151–209 is a hyperactive FTZ molecule. Therefore, the region encompassing amino acids 151–209 of FTZ is required in some manner for repression of FTZ activity. These results are discussed in relation to the current understanding of the mechanism of FTZ action.     

Male-male courtship behavior induced by ectopic expression of the Drosophila white gene: Role of sensory function and age

Male-male courtship behavior was recently reported to be induced in large populations of Drosophila (e.g., 600–1500 flies) by ectopic expression of the white (w) gene. Little is known about the basis of this behavior; in male-female courtship, sensory cues are believed to play an important role. Previous data are consistent with the possibility that misexpression of w causes abnormal reception or processing of sensory information. We show here that w-induced male-male courtship occurs in isolated pairs of flies. Thus the behavior does not depend on sensory cues found only among large populations of flies, or on cues produced only by a small subset of such populations. This finding enabled quantitative analysis of mechanisms that underlie the behavior. Specifically, male-male courtship does not depend on the reception of olfactory information, nor on the reception or generation of auditory cues, as determined by surgical ablation of antennae, maxillary palps, or wings. Although the rapid onset of the behavior following w induction suggested that its basis could lie in a modulation of sensory physiology, we found visual, olfactory, and gustatory function to be normal in physiological or behavioral tests. The only sensory deprivation to produce an effect on male-male courtship was testing under dim red light; the percentage of flies courting another male was reduced to one-fourth of control values. A striking age dependence of the behavior is also documented: courtship between paired male mini-w⁺ flies was not observed in tests of very young (1-day-old) flies, but occurs at high levels between the ages of 1 and 4 weeks. © 1996 John Wiley & Sons, Inc.     

Morphological and functional abnormalities in neuromuscular junctions of Drosophila melanogaster induced by the expression of human APP gene

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by the loss of neurocortical and hippocampal synapses that precedes amyloidosis and neurodegeneration and closely correlates with memory impairment. Mutations in the amyloid precursor protein (APP) cause familial AD and result in the increased production of amyloid-beta-protein (Abeta). To gain insights into synaptic effects of APP, we expressed APP, mutant form APP-Swedish and BACE in the motor neurons of fly larvae. We have shown that targeted expression of APP (APP-Swedish) in Drosophila larval motor neurons causes significant morphological and functional changes in neuromuscular junctions (NMJs): a dramatic increase in the number of synaptic buttons and changes in exocytosis as revealed by incorporation of the styryl dye FM4-64. Analysis of the number and distribution of mitochondria showed that motor neurons overexpressing APP (APP-Swedish) had a significant reduction of functional mitochondria in the presynaptic terminal. Significant synaptic abnormalities were observed for APP (APP-Swedish) and human beta-secretase (BACE) resulting in secretion of amyloid beta protein (Abeta). We suggest that APP participates in regulation of synaptic functions and its elevated expression leads to synaptic pathology independently from neurotoxic effects of Abeta.     

Disruption of SMN function by ectopic expression of the human SMN gene in Drosophila

Spinal muscular atrophy is a neurodegenerative disorder caused by mutations or deletions in the survival motor neuron (SMN) gene. We have cloned the Drosophila ortholog of SMN (DmSMN) and disrupted its function by ectopically expressing human SMN. This leads to pupal lethality caused by a dominant-negative effect, whereby human SMN may bind endogenous DmSMN resulting in non-functional DmSMN/human SMN hetero-complexes. Ectopic expression of truncated versions of DmSMN and yeast two-hybrid analysis show that the C-terminus of SMN is necessary and sufficient to replicate this effect. We have therefore generated a system which can be utilized to carry out suppressor and high-throughput screens, and provided in vivo evidence for the importance of SMN oligomerization for SMN function at the level of an organism as a whole.     

Cell-surface changes induced by ectopic expression of the murine homeobox gene Hox-3.3.

Murine homeobox-containing genes (Hox genes) are postulated as playing key roles in the establishment of the anterior-posterior embryonic body axis, possibly providing cells with positional cues. Little is known, however, concerning how cells might respond to homeobox gene expression to interpret these cues. Since changes in the cell-surface are central to many processes in early development we reasoned that cells expressing different complements of Hox genes might have different surface properties. In order to investigate this we have used the sensitive, non-disruptive technique of multiple two-phase aqueous partition, which is able to detect small differences on the surface of intact cells. Using this technique we have found that ectopic expression of the murine Hox-3.3 gene in cultured cells induces reproducible changes in the cell surface. Changes only occurred above a threshold level of gene expression, but above this level a correlation between surface change and gene expression was seen. The implications for the establishment of a 'Hox' code of homeobox genes acting to specifically change cell-surface properties are discussed.