Heat Shock Factor 1 (HSF1) is a transcription factor whose loss of function results in the inability of Hsf1(-/-) females to produce viable embryos, as a consequence of early developmental arrest. We previously demonstrated that maternal HSF1 is required in oocytes to regulate expression of chaperones, in particular Hsp90alpha, and is essential for the progression of meiotic maturation. In the present work, we used comparative morphological and biochemical analytic approaches to better understand how Hsf1(-/-) oocytes undergo irreversible cell death. We found that the metaphase II arrest in mature oocytes, cortical granule exocytosis and formation of pronuclei in zygotes were all impaired in Hsf1(-/-) mutants. Although oogenesis generated fully grown oocytes in follicles, intra-ovarian Hsf1(-/-) oocytes displayed ultrastructural abnormalities and contained dysfunctional mitochondria as well as elevated oxidant load. Finally, the apoptotic effector, caspase-3, was activated in most mutant oocytes and embryos, reflecting their commitment to apoptosis. In conclusion, our study shows that early post-ovulation events are particularly sensitive to oxidant insult, which abrogates the developmental competence of HSF1-depleted oocytes. They also reveal that Hsf1 knock-out mice constitute a genetic model that can be used to evaluate the importance of redox homeostasis in oocytes.
Forelimbs (FLs) and hindlimbs (HLs) develop complex musculoskeletal structures that rely on the deployment of a conserved developmental program. , a transcription factor gene with expression restricted to HL and absent from FL, plays an important role in generating HL features. The genomic mechanisms by which effects HL identity remain poorly understood. Here, we use expression profiling and analysis of direct Pitx1 targets to characterize the HL- and FL-restricted genetic programs in mouse and situate the -dependent gene network within the context of limb-specific gene regulation. We show that is a crucial component of a narrow network of HL-restricted regulators, acting on a developmental program that is shared between FL and HL. Pitx1 targets sites that are in a similar chromatin state in FL and HL and controls expression of patterning genes as well as the chondrogenic program, consistent with impaired chondrogenesis in HL. These findings support a model in which multifactorial actions of a limited number of HL regulators redirect the generic limb development program in order to generate the unique structural features of the limb.
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