在早期和中期果蝇胚胎中,Notch 和 delta mRNAs 表现出互补的蛋白质产生潜能模式。
Notch and delta mRNAs in early-stage and mid-stage drosophila embryos exhibit complementary patterns of protein-producing potentials.
机构信息
Department of Biology, University of Vermont, Burlington, Vermont 05405, USA.
出版信息
Dev Dyn. 2010 Apr;239(4):1220-33. doi: 10.1002/dvdy.22262.
Abstract
Notch and Delta proteins generate Notch signaling that specifies cell fates during animal development. There is an intriguing phenomenon in Drosophila embryogenesis that has not received much attention and whose significance to embryogenesis is unknown. Notch and Delta mRNAs expressed in early-stage embryos are shorter than their counterparts in mid-stage embryos. We show here that the difference in sizes is due to mRNA 3' processing at alternate polyadenylation sites. While the early-stage Notch mRNA has a lower protein-producing potential than the mid-stage Notch mRNA, the early-stage Delta mRNA has a higher protein-producing potential than the mid-stage Delta mRNA. Our data can explain the complementary patterns of Notch and Delta protein levels in early- and mid-stage embryos. Our data also raise the possibility that the manner and regulation of Notch signaling change in the course of embryogenesis and that this change is effected by 3' UTR and mRNA 3' processing factors.
摘要
Notch 和 Delta 蛋白产生 Notch 信号,在动物发育过程中指定细胞命运。在果蝇胚胎发生中有一个有趣的现象尚未引起太多关注,其对胚胎发生的意义尚不清楚。在早期胚胎中表达的 Notch 和 Delta mRNA 比中期胚胎中的短。我们在这里表明,大小差异是由于在交替多聚腺苷酸化位点进行 mRNA 3' 加工。虽然早期 Notch mRNA 的蛋白产生潜力低于中期 Notch mRNA,但早期 Delta mRNA 的蛋白产生潜力高于中期 Delta mRNA。我们的数据可以解释早期和中期胚胎中 Notch 和 Delta 蛋白水平的互补模式。我们的数据还提出了这样一种可能性,即 Notch 信号的方式和调节在胚胎发生过程中发生变化,这种变化是由 3'UTR 和 mRNA 3' 加工因子引起的。
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