The ability of both acute and chronic ethanol exposures to elicit cell death within specific embryonic and adult tissues is believed to partly underlie ethanol's pathogenicity; however, the mechanism underlying this cell death is unknown. This study partially characterized the mechanism of ethanol-induced neural crest cell death in a chick embryo model of fetal alcohol syndrome. In situ DNA end-labeling demonstrated this cell death was apoptotic and occurred at embryonic ethanol levels as low as 42 mM. Regardless of the initial exposure time, this apoptosis always appeared at a distinct developmental time point simultaneous with the normal deletion of a cranial neural crest subset. This suggested that ethanol might act through aberrant activation of the endogenous death pathway; however, ethanol exposure failed to induce two components of this pathway, the homeotic transcription factor msx-2 and the growth factor bone morphogenetic protein 4. Both endogenous and ethanol-induced death were blocked by local application of an interleukin-1beta converting enzyme/CED-3 protease (caspase) inhibitor, showing that the two paths converge mechanistically and suggesting the potential to prevent this aspect of ethanol's teratogenicity. Ethanol exposure did not significantly alter cell proliferation within neural crest-populated regions, suggesting that susceptibility to ethanol-induced death did not involve exit from the cell cycle. Apoptotic deletion of cranial neural crest could partially explain the craniofacial deficits characteristic of the fetal alcohol syndrome.
The ability of both acute and chronic ethanol exposures to elicit cell death within specific embryonic and adult tissues is believed to partly underlie ethanol's pathogenicity; however, the mechanism underlying this cell death is unknown. This study partially characterized the mechanism of ethanol-induced neural crest cell death in a chick embryo model of fetal alcohol syndrome. In situ DNA end-labeling demonstrated this cell death was apoptotic and occurred at embryonic ethanol levels as low as 42 mM. Regardless of the initial exposure time, this apoptosis always appeared at a distinct developmental time point simultaneous with the normal deletion of a cranial neural crest subset. This suggested that ethanol might act through aberrant activation of the endogenous death pathway; however, ethanol exposure failed to induce two components of this pathway, the homeotic transcription factor msx-2 and the growth factor bone morphogenetic protein 4. Both endogenous and ethanol-induced death were blocked by local application of an interleukin-1beta converting enzyme/CED-3 protease (caspase) inhibitor, showing that the two paths converge mechanistically and suggesting the potential to prevent this aspect of ethanol's teratogenicity. Ethanol exposure did not significantly alter cell proliferation within neural crest-populated regions, suggesting that susceptibility to ethanol-induced death did not involve exit from the cell cycle. Apoptotic deletion of cranial neural crest could partially explain the craniofacial deficits characteristic of the fetal alcohol syndrome.
We propose that ethanol's effects on craniofacial development are multifactoral, and these influences may include susceptibility to apoptosis, regenerative capacity, and compensatory outgrowth of the facial primordia. The embryo's genetic background may modulate these events. The high and low responder chick strains are useful tools to dissect these contributions.
We propose that ethanol's effects on craniofacial development are multifactoral, and these influences may include susceptibility to apoptosis, regenerative capacity, and compensatory outgrowth of the facial primordia. The embryo's genetic background may modulate these events. The high and low responder chick strains are useful tools to dissect these contributions.
A second cytadhesin-like protein, MGC2, was identified in the avian respiratory pathogen Mycoplasma gallisepticum. The 912-nucleotide mgc2 gene encodes a 32.6-kDa protein with 40.9 and 31.4% identity with the M. pneumoniae P30 andM. genitalium P32 cytadhesins, respectively. Functional studies with reverse transcription-PCR, immunoblotting, double-sided immunogold labeling, and attachment inhibition assays demonstrated homology to the human mycoplasmal P30 and P32 cytadhesins. These findings suggest that there is a family of cytadhesin genes conserved among pathogenic mycoplasmas infecting widely divergent hosts.
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