In Vitro Folliculogenesis in Mammalian Models: A Computational Biology Study.

Nicola Bernabò,Maurizio Monaci,Giorgia Buoncuore,Barbara Barboni,Umberto Tosi,Giulia Capacchietti,Martina Crociati,Chiara Di Berardino,Alessia Peserico

doi:10.3389/fmolb.2021.737912

Nicola Bernabò, Maurizio Monaci + Show 7 more

Open Access

https://doi.org/10.3389/fmolb.2021.737912

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Abstract

In vitro folliculogenesis (ivF) has been proposed as an emerging technology to support follicle growth and oocyte development. It holds a great deal of attraction from preserving human fertility to improving animal reproductive biotechnology. Despite the mice model, where live offspring have been achieved,in medium-sized mammals, ivF has not been validated yet. Thus, the employment of a network theory approach has been proposed for interpreting the large amount of ivF information collected to date in different mammalian models in order to identify the controllers of the in vitro system. The WoS-derived data generated a scale-free network, easily navigable including 641 nodes and 2089 links. A limited number of controllers (7.2%) are responsible for network robustness by preserving it against random damage. The network nodes were stratified in a coherent biological manner on three layers: the input was composed of systemic hormones and somatic-oocyte paracrine factors; the intermediate one recognized mainly key signaling molecules such as PI3K, KL, JAK-STAT, SMAD4, and cAMP; and the output layer molecules were related to functional ivF endpoints such as the FSH receptor and steroidogenesis. Notably, the phenotypes of knock-out mice previously developed for hub.BN indirectly corroborate their biological relevance in early folliculogenesis. Finally, taking advantage of the STRING analysis approach, further controllers belonging to the metabolic axis backbone were identified, such as mTOR/FOXO, FOXO3/SIRT1, and VEGF, which have been poorly considered in ivF to date. Overall, this in silico study identifies new metabolic sensor molecules controlling ivF serving as a basis for designing innovative diagnostic and treatment methods to preserve female fertility.

Highlights

Assisted reproductive technologies (ARTs) represent a consolidated clinical practice, which have resulted in several million births since 1978 (Adamson et al, 2018) (International Federation of Fertility Societies’ Surveillance, 2019)
Since the first attempt in the field of in vitro folliculogenesis in 1996 (Eppig, 1996) (O’Brien et al, 2003), many efforts are made to set up new culture systems able to support in vitro growth of early-stage follicles toward competent oocytes (Laronda et al, 2017) (Xiao et al, 2015) (Xiao et al, 2017) (McLaughlin et al, 2018)
The 2D Kernel density estimation (KDE) approach allowed to select those with a major modulatory role on the network information flow by identifying either cultural functional endpoints or in vitro follicle controllers such as systemic hormones and local factors (Matzuk et al, 2002)

Summary

Introduction

Assisted reproductive technologies (ARTs) represent a consolidated clinical practice, which have resulted in several million births since 1978 (Adamson et al, 2018) (International Federation of Fertility Societies’ Surveillance, 2019). In vitro Folliculogenesis Network Study cryopreservation procedures but not managed (Martinez et al, 2017) In this context, the development of protocols aiming to obtain and fertilize mature oocytes from immature follicles grown outside the body could represent a useful strategy to recover the largest pool of ovarian gametes by promoting their in vitro growth and differentiation. The development of protocols aiming to obtain and fertilize mature oocytes from immature follicles grown outside the body could represent a useful strategy to recover the largest pool of ovarian gametes by promoting their in vitro growth and differentiation This follicle rescue approach could be applied as a possible future clinical strategy to preserve the ovarian reserve, as in the case of adult and prepubertal patients with cancer, where ovarian transplantation may expose to the risk of reintroducing malignant cells (Herta et al, 2018) (De Vos et al, 2014). Based on similarities in physiology and anatomy of the ovaries, folliculogenesis timing, and the follicle size (Barboni et al, 2011) (Bähr and Wolf, 2012) (Telfer and Zelinski, 2013), medium-sized mono-ovulatory mammals are commonly accepted as a translational model, and they are increasingly considered as being very relevant for human preimplantation reproductive research

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