CD147 mediates S protein pseudovirus of SARS-CoV-2 infection and its induction of spermatogonia apoptosis.

Male cases diagnosed COVID-19 with more complications and higher mortality compared with females, and the overall consequences of male sex hormones and semen parameters deterioration were observed in COVID-19 patients, whereas the involvement and mechanism for spermatogenic cell remains unclear. The study was aimed to investigate the infection mode of S protein (D614G) pseudovirus (pseu-S-D614G) to spermatogenic cells, as well as the influence on cell growth. Both mouse spermatogonia (GC-1 cell, immortalized spermatogonia) and spermatocyte (GC-2 cell, immortalized spermatocytes) were used to detect the infection of pseu-S-D614G of SARS-CoV-2, and further explored the effect of SARS-CoV-2-spike protein (S-protein) and SARS-CoV-2-spike protein (omicron) (O-protein) on GC-1 cell apoptosis and proliferation. The data showed that the pseu-S-D614G invaded into GC-1 cells through either human ACE2 (hACE2) or human CD147 (hCD147), whereas GC-2 cells were insensitive to viral infection. In addition, the apoptosis and proliferation suppression inflicted by S-protein and O-protein on GC-1 cells was through Bax-Caspase3 signaling rather than arresting cell cycle progression. These findings suggest that CD147, apart from ACE2, may be a potential receptor for SARS-CoV-2 infection in testicular tissues, and that the apoptotic effect was induced in spermatogonia cells by S-protein or O-protein, eventually resulted in the damage to male fertility.

Mitochondrial Fission in Nickel Nanoparticle-Induced Reproductive Toxicity: An In Vitro GC-1 Cell Study.

Reproductive disorders and declining fertility rates are significant public health concerns affecting birth rates and future populations. Male infertility, often due to spermatogenesis defects, may be linked to environmental pollutants like nickel nanoparticles (Ni NPs). Ni NPs are extensively utilized across different industries. Nevertheless, their potential adverse effects cannot be overlooked. Previous studies have linked the reproductive toxicity induced by Ni NPs with disturbances in mitochondrial function. Mitochondrial division/fusion dynamics are crucial to their proper function, yet little is known about how Ni NPs perturb these dynamics and whether such perturbation contributes to the impairment of the male reproductive system. Herein, we demonstrated that the exposure of Ni NPs to the mouse-derived spermatogonia cell line (GC-1 cells) triggered DRP1-mediated mitochondrial division and the enhanced impairment of mitochondria, consequently promoting mitochondria-dependent cell apoptosis. Notably, both the mitochondrial division inhibitor (Mdivi-1) and lentiviral-transfected cells with low expression of Dnm1l-DK in these cells could mitigate the toxic effects induced by Ni NPs, pointing to the potential role of mitochondrial dynamics in Ni NP-induced reproductive toxicity. Collectively, our work contributes to the understanding of the mechanisms by which Ni NPs can impact male reproductive function and identifies mitochondrial division as a potential target for intervention.

Fluid dynamic design for mitigating undesired cell effects and its application to testis cell response testing to endocrine disruptors.

Microfluidic devices have emerged as powerful tools for cell-based experiments, offering a controlled microenvironment that mimic the conditions within the body. Numerous cell experiment studies have successfully utilized microfluidic channels to achieve various new scientific discoveries. However, it has been often overlooked that undesired and unnoticed propagation of cellular molecules in such bio-microfluidic channel systems can have a negative impact on the experimental results. Thus, more careful designing is required to minimize such unwanted issues through deeper understanding and careful control of chemically and physically predominant factors at the microscopic scale. In this paper, we introduce a new approach to improve microfluidic channel design, specifically targeting the mitigation of the aforementioned challenges. To minimize the occurrence of undesired cell positioning upstream from the main test section where a concentration gradient field locates, an additional narrow port structure was devised between the microfluidic upstream channel and each inlet reservoir. This port also functioned as a passive lock that hold the flow at rest via fluid-air surface tension, which facilitated manual movement of the device even when cell attachment was not achieved completely. To demonstrate the practicability of the system, we conducted experiments and diffusion simulations on the effect of endocrine disruptors on germ cells. To this end, a bisphenol-A (BPA) concentration gradient was generated in the main channel of the system at BPA concentrations ranging from 120.8 µM to 79.3 µM, and the proliferation of GC-1 cells in the BPA gradient environment was quantitatively evaluated. The features and concepts of the introduced design is to minimize unexpected and ignored error sources, which will be one of the issues to be considered in the development of microfluidic systems to explore extremely delicate cellular phenomena.

[Role of the lncRNA H19/ microRNA-203a/PTEN axis in ischemia-reperfusion injury of mouse GC-1 cells and its mechanism].

OBJECTIVE: To investigate the expression of long non-coding RNA (lncRNA) H19 in mouse GC-1 cells in vitro and its effects on the proliferation and apoptosis of GC-1 cells. METHODS: We established an in vitro hypoxia-reoxygenation model in GC-1 cells and detected the expression of lncRNA H19 in the GC-1 cells at different time points of reoxygenation injury by qRT-PCR. We determined the effects of silencing lncRNA H19 on the proliferation and apoptosis of the GC-1 cells by MTT and flow cytometry, the expressions of apoptosis-related proteins Bax and caspase-3 in the GC-1 cells by Western blot, and the expressions of microRNA-203a and PTEN by qRT-PCR and Western blot, respectively. RESULTS: With the prolonging of the time of reoxygenation injury, the expression of lncRNA H19 was increased significantly in the GC-1 cells and peaked at 3-hour hypoxia and 12-hour reoxygenation, but that of microRNA-203a markedly decreased. Silencing lncRNA H19 enhanced the proliferation and inhibited the apoptosis of the GC-1 cells, and up-regulated the expression of microRNA-203a and down-regulated that of PTEN in the GC-1 cells. CONCLUSIONS: LncRNA H19 is highly expressed in GC-1 cells in vitro, which may influence the proliferation and apoptosis of GC-1 cells by regulating the microRNA-203a /PTEN signaling pathway.

ANKRD49 inhibits etoposide-induced intrinsic apoptosis of GC-1 cells by modulating NF-κB signaling.

Spermatogenesis is a complicated process that is tightly regulated by the well-coordinated expression of a series of genes in the testes. Ankyrin repeat domain-containing protein 49 (ANKRD49), an evolutionarily conserved protein highly expressed in the testes, is mainly found in spermatogonia, spermatocytes, and round spermatids. However, the exact function of ANKRD49 in spermatogenesis has remained elusive. In this study, we sought to investigate the role of ANKRD49 in apoptosis and determine the mechanism underlying this process in male germ cell-derived GC-1 cells. Nuclear staining with Hoechst 33258 and annexin V-FITC/PI, as well as analysis of caspase 3 activity, mitochondrial membrane potential, and apoptotic protein expression, showed that etoposide-induced apoptosis was attenuated by ANKRD49 overexpression but promoted by RNA interference-induced ANKRD49 knockdown. Furthermore, assessment of the levels of caspase 9, caspase 8, and proteins of the Bcl-2 family revealed ANKRD49 to be involved in an intrinsic apoptosis pathway. Examination of the subcellular distribution of the NF-κB p65 subunit after treatment with an NF-κB signaling inhibitor or p65 small interfering RNA demonstrated that ANKRD49 modulated etoposide-induced GC-1 cell apoptosis via the NF-κB pathway. Taken together, these results suggest that ANKRD49 plays an important role in reducing intrinsic apoptosis of GC-1 cells by modulating the NF-κB signaling pathway.