Department of cellular and Molecular medicine, Faculty of Medicine, University of Ottawa, Ottawa, Canada.
Department of Pharmacology, Karaj Branch, Islamic Azad University, Karaj, Iran.
Cell Tissue Bank. 2024 Mar;25(1):231-243. doi: 10.1007/s10561-023-10093-1. Epub 2023 Sep 7.
Spermatogonia stem cells (SSCs) are a unique cell population maintaining male spermatogenesis during life, through their potential for proliferation and differentiation. The application of silicon nanoparticles (SNs) and hyaluronic acid (HA) to induce the differentiation of SSCs seems promising. Herein, we investigate the effect of SN and HA scaffolds on the progression of SSCs spermatogenesis in mice. Initially SSCs were isolated from healthy immature mice and cultured on prepared scaffolds (HA, SN, and HA/SN) in a 3D culture system. Then viability of SSCs cultured on scaffolds was examined using MTT assay and Acridine Orange staining. Then SSCs cultured on scaffolds were transplanted into epididymal adipose tissue (EAT) in mature mice and the result was studied by H&E and IHC staining 8 weeks after transplantation. MTT and Acridine Orange analysis revealed that among three different scaffolds HA/SN based scaffold causes considerable toxicity on SSCs (P < 0.05) while H&E staining showed that culture of SSCs on HA, SN, and HA/SN scaffolds has a positive effect on the progression of SSCs spermatogenesis after transplantation into EAT. IHC staining identified TP1, TEKT1, and PLZF as crucial biomarkers in the spermatogenesis development of SSCs transplanted to EAT. According to the presence of these biomarkers in different experimental groups, we found the most spermatogenesis development in SSCs cultured on HA/SN scaffold (PLZF, P < 0.01) (TEKT1, P < 0.01) (TP1, P < 0.001). Our study showed that, although the cytotoxic effect of the HA/SN scaffold decreases the viability rate of SSCs; however, SSCs that survive on HA/SN scaffold showed more ability to progress in spermatogenesis after transplantation into EAT.
精原干细胞(SSCs)是一种独特的细胞群体,通过其增殖和分化的潜力,在生命过程中维持男性精子发生。硅纳米粒子(SNs)和透明质酸(HA)的应用似乎有望诱导 SSCs 的分化。在此,我们研究了 SN 和 HA 支架对小鼠 SSCs 精子发生进展的影响。首先,我们从健康的未成熟小鼠中分离 SSCs,并在 3D 培养系统中在制备的支架(HA、SN 和 HA/SN)上培养它们。然后使用 MTT 测定法和吖啶橙染色法检查在支架上培养的 SSCs 的活力。然后将在支架上培养的 SSCs 移植到成熟小鼠的附睾脂肪组织(EAT)中,并在移植后 8 周通过 H&E 和 IHC 染色研究结果。MTT 和吖啶橙分析表明,在三种不同的支架中,基于 HA/SN 的支架对 SSCs 具有相当大的毒性(P<0.05),而 H&E 染色表明,在 EAT 中移植后,在 HA、SN 和 HA/SN 支架上培养 SSCs 对 SSCs 精子发生的进展有积极影响。IHC 染色确定 TP1、TEKT1 和 PLZF 是移植到 EAT 的 SSCs 精子发生发育的关键生物标志物。根据这些生物标志物在不同实验组中的存在情况,我们发现 SSCs 在 HA/SN 支架上培养时具有最高的精子发生发育能力(PLZF,P<0.01)(TEKT1,P<0.01)(TP1,P<0.001)。我们的研究表明,尽管 HA/SN 支架的细胞毒性作用降低了 SSCs 的活力,但在 HA/SN 支架上存活的 SSCs 在移植到 EAT 后具有更强的进展为精子发生的能力。
