Autophagy is involved in granulosa cell death and follicular atresia in ewe ovaries.

In mammalian ovaries, most follicles do not ovulate and are eliminated by atresia, which primarily depends on granulosa cell (GC) apoptosis. Autophagy is an alternative mechanism involved in follicle depletion in mammals through independent or tandem action with apoptosis. However, follicular autophagy has not yet been investigated in sheep; therefore, the present study aimed to investigate the involvement of autophagy in atresia among a pool of growing antral follicles in ewe ovaries. The abundance of the autophagic marker LC3B-II was determined using western blotting in GCs collected from ewe antral follicles. The antral follicles were classified as healthy or atretic based on morphological criteria and steroid measurements in follicular fluid (FF). Immunofluorescence and confocal microscopy analyses were performed on GCs to evaluate the presence of autophagic proteins and their subcellular localisation. Caspase-3 and DNA fragmentation were assessed using western blotting and TUNEL assays, respectively, in the same GC population to investigate the simultaneous apoptosis. The novel results of this study demonstrated enhanced LC3B-II protein expression in GCs of atretic follicles compared to that of healthy ones (1.3-fold increase; P = 0.0001, ANOVA), indicating a correlation between autophagy enhancement in GCs and antral follicular atresia. Autophagy, either functioning independently or in tandem with apoptosis, may be involved in the atresia of growing antral follicles in ewe ovaries because atretic GCs also showed high levels of apoptotic markers. The findings of this study might have important implication on scientific understanding of ovarian follicle dynamics.

Oocyte activation is a cytoplasm-confined event so far: what about the nucleus?

The fertilizing spermatozoa induce a Ca2+ oscillatory pattern, the universal hallmark of oocyte activation, in all sexually reproducing animals. Assisted reproductive technologies (ARTs) like intracytoplasmic sperm injection (ICSI) bypass the physiological pathway; however, while a normal Ca2+ release pattern occurs in some species, particularly humans, artificial activation is compulsory for ICSI-fertilized oocytes to develop in most farm animals. Unlike the normal oscillatory pattern, most artificial activation protocols induce a single Ca2+ spike, undermining proper ICSI-derived embryo development in these species. Curiously, diploid parthenogenetic embryos activated by the same treatments develop normally at high frequencies and implant upon transfer in the uterus. We hypothesized that, at least in ruminant embryos, the oscillatory calcium waves late in the first cell cycle target preferentially the paternal pronucleus and are fundamentally important for paternal nuclear remodeling. We believe that Ca2+ signaling is central to full totipotency deployment of the paternal genome. Research in this area could highlight the asymmetry between the parental genome reprogramming timing/mechanisms in early development and impact ARTs like ICSI and cloning.

Reviving vacuum-dried encapsulated ram spermatozoa via ICSI after 2 years of storage.

Introduction: Freeze-drying techniques give alternative preservation mammalian spermatozoa without liquid nitrogen. However, most of the work has been conducted in the laboratory mouse, while little information has been gathered on large animals that could also benefit from this kind of storage. Methods: This work adapted a technique known as vacuum-drying encapsulation (VDE), originally developed for nucleic acid conservation in anhydrous state, to ram spermatozoa, and compared it to canonical lyophilization (FD), testing long-term storage at room temperature (RT) and 4°C. Results and discussion: The results demonstrated better structural stability, namely lipid composition and DNA integrity, in VDE spermatozoa than FD ones, with outcomes at RT storage comparable to 4°C. Likewise, in VDE the embryonic development was higher than in FD samples (12.8% vs. 8.7%, p < 0.001, respectively). Our findings indicated that in large mammals, it is important to consider dehydration-related changes in sperm polyunsaturated fatty acids coupled with DNA alterations, given their crucial role in embryonic development.