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In the last few decades, microplastics (MPs) have been among the emerging environmental pollutants that have received serious attention from scientists and the general population due to their wide range of potentially harmful effects on living organisms. MPs may originate from primary sources (micro-sized plastics manufactured on purpose) and secondary sources (breakdown of large plastic items through physical, chemical, and biological processes). Consequently, serious concerns are escalating because MPs can be easily disseminated and contaminate environments, including terrestrial, air, groundwater, marine, and freshwater systems. Furthermore, an exposure to even low doses of MPs during the early developmental stage may induce long-term health effects, even later in life. Accordingly, this study aims to gather the current evidence regarding the effects of MPs exposure on vital body systems, including the digestive, reproductive, central nervous, immune, and circulatory systems, during the early developmental stage. In addition, this study provides essential information about the possible emergence of various diseases later in life (i.e., adulthood).

The spermatogonial stem cell (SSC) is a unique adult stem cell that requires tight physiological regulation during development and adulthood. As the foundation of spermatogenesis, SSCs are a potential tool for the treatment of infertility. Understanding the factors that are necessary for lifelong maintenance of a SSC pool in vivo is essential for successful in vitro expansion and safe downstream clinical usage. This review focused on the current knowledge of prepubertal testicular development and germ cell metabolism in different species, and implications for translational medicine. The significance of metabolism for cell biology, stem cell integrity, and fate decisions is discussed in general and in the context of SSC in vivo maintenance, differentiation, and in vitro expansion.

There is high clinical demand for the resolution of tendinopathies, which affect mainly adult individuals and animals. Tendon damage resolution during the adult lifetime is not as effective as in earlier stages where complete restoration of tendon structure and property occurs. However, the molecular mechanisms underlying tendon regeneration remain unknown, limiting the development of targeted therapies. The research aim was to draw a comparative map of molecules that control tenogenesis and to exploit systems biology to model their signaling cascades and physiological paths. Using current literature data on molecular interactions in early tendon development, species-specific data collections were created. Then, computational analysis was used to construct Tendon NETworks in which information flow and molecular links were traced, prioritized, and enriched. Species-specific Tendon NETworks generated a data-driven computational framework based on three operative levels and a stage-dependent set of molecules and interactions (embryo–fetal or prepubertal) responsible, respectively, for signaling differentiation and morphogenesis, shaping tendon transcriptional program and downstream modeling of its fibrillogenesis toward a mature tissue. The computational network enrichment unveiled a more complex hierarchical organization of molecule interactions assigning a central role to neuro and endocrine axes which are novel and only partially explored systems for tenogenesis. Overall, this study emphasizes the value of system biology in linking the currently available disjointed molecular data, by establishing the direction and priority of signaling flows. Simultaneously, computational enrichment was critical in revealing new nodes and pathways to watch out for in promoting biomedical advances in tendon healing and developing targeted therapeutic strategies to improve current clinical interventions.

Endocannabinoids are lipidic modulators able to bind cannabinoid receptors (CNRs). Two types of CNRs have been cloned, CNR1 (central) and CNR2 (peripheral). The objectives of the present study were to investigate the expression pattern of CNR1 in the rat testis during prepubertal development and to define the CNR1 spatiotemporal pattern. From 31 to 60 days of age, CNR1 was immunolocalized in round elongating spermatids and spermatozoa, suggesting an important role for this receptor in spermatogenesis. From 14 to 60 days of age, adult Leydig cells (ALCs) at different developmental stages were positive for CNR1. In particular, CNR1 expression in differentiating ALCs was negatively correlated to cell division. Bromodeoxyuridine uptake experiments on serial sections showed that immature Leydig cells in mitosis were negative for CNR1; in contrast, immature nonmitotic Leydig cells were positive for CNR1. A further observation of few ALCs in CNR1KO mice validates the role of CNR1 during proliferative activity involved in ALC differentiation. In addition, starting from 41 days of age, a faint CNR1 signal was also observed in Sertoli cells. Taken together, these results demonstrate the first clear evidence (to our knowledge) of CNR1 in mammalian germinal epithelium, ALCs, and Sertoli cells and indicate that differentiation of ALCs may depend on the endocannabinoid system.

Endocannabinoids are lipidic modulators able to bind cannabinoid receptors (CNRs). Two types of CNRs have been cloned, CNR1 (central) and CNR2 (peripheral). The objectives of the present study were to investigate the expression pattern of CNR1 in the rat testis during prepubertal development and to define the CNR1 spatiotemporal pattern. From 31 to 60 days of age, CNR1 was immunolocalized in round elongating spermatids and spermatozoa, suggesting an important role for this receptor in spermatogenesis. From 14 to 60 days of age, adult Leydig cells (ALCs) at different developmental stages were positive for CNR1. In particular, CNR1 expression in differentiating ALCs was negatively correlated to cell division. Bromodeoxyuridine uptake experiments on serial sections showed that immature Leydig cells in mitosis were negative for CNR1; in contrast, immature nonmitotic Leydig cells were positive for CNR1. A further observation of few ALCs in CNR1KO mice validates the role of CNR1 during proliferative activity involved in ALC differentiation. In addition, starting from 41 days of age, a faint CNR1 signal was also observed in Sertoli cells. Taken together, these results demonstrate the first clear evidence (to our knowledge) of CNR1 in mammalian germinal epithelium, ALCs, and Sertoli cells and indicate that differentiation of ALCs may depend on the endocannabinoid system.

The juvenile in vitro embryo transfer technology holds the potential to accelerate livestock breeding. However, its application is limited due to the weak in vitro development of oocytes and embryos from prepubertal lambs. To dissect the regulatory networks of gene expression of sheep embryos and identify the defects in gene expression in prepubertal lamb embryos during the oocyte-to-embryo transition, full-length RNA sequencing and whole-genome bisulfite sequencing based on trace cells were conducted on in vitro-derived embryos generated from adult sheep and prepubertal lamb oocytes. We found that the maternal transcript degradation occurred selectively in adult sheep embryos in multiple waves and was most completed until the morula stage. Major embryonic genome activation was found to occur at the morula stage. By comparing with the patterns of adult embryos, we observed incomplete maternal transcript degradation and abnormal embryonic genome activation in lamb embryos and analyzed their potential molecular mechanisms. Furthermore, we explored dynamic DNA methylation concerning the paternal and maternal genomes during the preimplantation development of sheep embryos, revealing the negative regulatory role of promoter DNA methylation on embryonic genome activation process. Lamb embryos generally displayed higher DNA methylation levels than adults, potentially repressing the embryonic genome activation gene expression, especially the genes associated with ribosomal and mitochondrial organization. We also found abnormalities in the methylation status of imprinted genes in lamb embryos. Our findings advance the understanding of sheep in vitro embryo development and offer insights for improving the juvenile in vitro embryo transfer technology in livestock. Summary Sentence Incomplete maternal transcript degradation, abnormal embryonic genome activation, and aberrant genomic methylation were found in preimplantation embryos derived from prepubertal lamb oocytes. Graphical Abstract

Background Clinical studies indicate chemotherapy agents used in childhood cancer treatment regimens may impact future fertility. However, effects of individual agents on prepubertal human testis, necessary to identify later risk, have not been determined. The study aimed to investigate the impact of cisplatin, commonly used in childhood cancer, on immature (foetal and prepubertal) human testicular tissues. Comparison was made with carboplatin, which is used as an alternative to cisplatin in order to reduce toxicity in healthy tissues. Methods We developed an organotypic culture system combined with xenografting to determine the effect of clinically-relevant exposure to platinum-based chemotherapeutics on human testis. Human foetal and prepubertal testicular tissues were cultured and exposed to cisplatin, carboplatin or vehicle for 24 h, followed by 24–240 h in culture or long-term xenografting. Survival, proliferation and apoptosis of prepubertal germ stem cell populations (gonocytes and spermatogonia), critical for sperm production in adulthood, were quantified. Results Cisplatin exposure resulted in a significant reduction in the total number of germ cells (− 44%, p  < 0.0001) in human foetal testis, which involved an initial loss of gonocytes followed by a significant reduction in spermatogonia. This coincided with a reduction (− 70%, p  < 0.05) in germ cell proliferation. Cisplatin exposure resulted in similar effects on total germ cell number (including spermatogonial stem cells) in prepubertal human testicular tissues, demonstrating direct relevance to childhood cancer patients. Xenografting of cisplatin-exposed human foetal testicular tissue demonstrated that germ cell loss (− 42%, p  < 0.01) persisted at 12 weeks. Comparison between exposures to human-relevant concentrations of cisplatin and carboplatin revealed a very similar degree of germ cell loss at 240 h post-exposure. Conclusions This is the first demonstration of direct effects of chemotherapy exposure on germ cell populations in human foetal and prepubertal testis, demonstrating platinum-induced loss of all germ cell populations, and similar effects of cisplatin or carboplatin. Furthermore, these experimental approaches can be used to determine the effects of established and novel cancer therapies on the developing testis that will inform fertility counselling and development of strategies to preserve fertility in children with cancer.

The intricate mechanisms driving oocyte maturation remain only partially understood, especially within the domains of domestic animal reproduction and translational medicine. In the case of prepubertal girls, the clinical challenge is especially pronounced, as ovarian tissue cryopreservation‐though promising‐remains an experimental technique necessitating rigorous scientific validation to guarantee the developmental potential of preserved materials and facilitate broader clinical adoption. To address these knowledge gaps, while considering the ethical implications, we applied transcriptome and translatome sequencing to comprehensively profile the transcriptional and translational dynamics of oocyte maturation in adult and prepubertal goats. Our analyses uncovered a sequential transition in gene expression regulation, shifting from cytoplasmic processes to chromosome segregation during the maturation process. Comparative profiling between adult and prepubertal goat oocytes revealed critical regulatory factors essential for prepubertal oocyte maturation. These include genes involved in organelle function ( GTPBP4 and TOMM7 ), spindle organisation ( CKS2 , CCP110 , CKAP5 and ESCO1 ) and chromosome segregation ( CENPE , CENPF , CENPN and SGO2 ). Functional validation through in vitro maturation experiments demonstrated that GTPBP4 significantly enhances the developmental competence of prepubertal goat oocytes. This enhancement occurs through mechanisms that promote cell cycle progression, organelle maturation and mRNA translation. These findings provide a detailed map of the molecular events underpinning goat oocyte maturation and offer new perspectives on the developmental strategies required for oocyte competence in prepubertal females. Translating these insights to humans, this research highlights potential fertility preservation strategies for prepubertal girls, such as ovarian tissue cryopreservation and transplantation, in vitro follicle culture, meiotic maturation and artificial ovary technologies. Moreover, the identified mechanisms have significant implications for improving reproductive efficiency in domestic animal breeding, bridging basic research and applied science.