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Molecular Mechanisms and Determinants of Species Sensitivity in Thalidomide TeratogenesisLee, Crystal J. J. 14 August 2013 (has links)
The expanding therapeutic use of thalidomide (TD) remains limited by its species-specific teratogenicity in humans and rabbits, but not rodents.
The R and S isomers of TD may be selectively responsible for its respective therapeutic and teratogenic effects, but rapid in vivo racemization makes this impossible to confirm. Fluorothalidomide (FTD), a fluorinated TD analogue with stable, non-racemizing isomers, may serve as a model compound for determining stereoselective effects. In vivo, FTD was undetectable in plasma, suggesting rapid breakdown, as confirmed in vitro, where FTD hydrolyzed up to 22-fold faster than TD. Unlike TD, FTD in pregnant rabbits and mice was highly toxic and lethal to both dams and fetuses. In rabbit embryo culture, FTD initiated optic (eye) vesicle and hindbrain but not classic limb bud embryopathies. Chemical instability, potent general toxicity and absence of limb bud embryopathies make FTD an unsuitable stereoselective model for TD teratogenesis.
TD teratogenesis may involve its bioactivation by embryonic prostaglandin H synthases (PHSs) to a free radical intermediate that increases embryopathic reactive oxygen species (ROS) formation. However, the teratogenic potential of rapidly formed TD hydrolysis products and the determinants of species-specific teratogenesis are unclear.
For some teratogens, mouse strains that are resistant in vivo are susceptible in embryo culture, suggesting maternal and/or placental determinants of risk. However, TD and two hydrolysis products, 2-phthalimidoglutaramic acid (PGMA) and 2-phthalimidoglutaraic acid (PGA), were non-embryopathic in CD-1 mouse embryo culture. Also, mice deficient in oxoguanine glycosylase 1 (OGG1), which repairs oxidatively damaged DNA, were resistant to TD embryopathies in culture and in vivo. Therefore, murine resistance to TD teratogenesis is dependent on embryonic factors, rather than maternal/placental determinants or increased DNA repair.
In contrast, rabbit embryos exposed in culture to TD, PGMA and PGA exhibited head/brain, otic (ear) vesicle and classic limb bud embryopathies, validating the first mammalian embryo culture model for TD teratogenesis and providing the first evidence of a teratogenic role for TD hydrolysis products. Pretreatment with eicosatetraynoic acid (ETYA), a dual PHS/lipoxygenase inhibitor, or phenylbutylnitrone (PBN), a free radical spin trapping agent, completely blocked TD, PGMA and PGA-initiated embryopathies, implicating a PHS-dependent, ROS-mediated embryopathic mechanism.
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Molecular Mechanisms and Determinants of Species Sensitivity in Thalidomide TeratogenesisLee, Crystal J. J. 14 August 2013 (has links)
The expanding therapeutic use of thalidomide (TD) remains limited by its species-specific teratogenicity in humans and rabbits, but not rodents.
The R and S isomers of TD may be selectively responsible for its respective therapeutic and teratogenic effects, but rapid in vivo racemization makes this impossible to confirm. Fluorothalidomide (FTD), a fluorinated TD analogue with stable, non-racemizing isomers, may serve as a model compound for determining stereoselective effects. In vivo, FTD was undetectable in plasma, suggesting rapid breakdown, as confirmed in vitro, where FTD hydrolyzed up to 22-fold faster than TD. Unlike TD, FTD in pregnant rabbits and mice was highly toxic and lethal to both dams and fetuses. In rabbit embryo culture, FTD initiated optic (eye) vesicle and hindbrain but not classic limb bud embryopathies. Chemical instability, potent general toxicity and absence of limb bud embryopathies make FTD an unsuitable stereoselective model for TD teratogenesis.
TD teratogenesis may involve its bioactivation by embryonic prostaglandin H synthases (PHSs) to a free radical intermediate that increases embryopathic reactive oxygen species (ROS) formation. However, the teratogenic potential of rapidly formed TD hydrolysis products and the determinants of species-specific teratogenesis are unclear.
For some teratogens, mouse strains that are resistant in vivo are susceptible in embryo culture, suggesting maternal and/or placental determinants of risk. However, TD and two hydrolysis products, 2-phthalimidoglutaramic acid (PGMA) and 2-phthalimidoglutaraic acid (PGA), were non-embryopathic in CD-1 mouse embryo culture. Also, mice deficient in oxoguanine glycosylase 1 (OGG1), which repairs oxidatively damaged DNA, were resistant to TD embryopathies in culture and in vivo. Therefore, murine resistance to TD teratogenesis is dependent on embryonic factors, rather than maternal/placental determinants or increased DNA repair.
In contrast, rabbit embryos exposed in culture to TD, PGMA and PGA exhibited head/brain, otic (ear) vesicle and classic limb bud embryopathies, validating the first mammalian embryo culture model for TD teratogenesis and providing the first evidence of a teratogenic role for TD hydrolysis products. Pretreatment with eicosatetraynoic acid (ETYA), a dual PHS/lipoxygenase inhibitor, or phenylbutylnitrone (PBN), a free radical spin trapping agent, completely blocked TD, PGMA and PGA-initiated embryopathies, implicating a PHS-dependent, ROS-mediated embryopathic mechanism.
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