Laboratory for Reproductive Immunology, NHC Key Lab of Reproduction Regulation (Shanghai Institute of Planned Parenthood Research), Shanghai Key Laboratory of Female Reproductive Endocrine Related Diseases, Hospital of Obstetrics and Gynecology, Fudan University Shanghai Medical College, Shanghai, China.
Department of Immunology, Medical College of Soochow University, Suzhou, Jiangsu, China.
Hum Reprod. 2020 Jul 1;35(7):1537-1552. doi: 10.1093/humrep/deaa118.
What is the role of pigment epithelium-derived factor (PEDF) from decidual natural killer (dNK) cells during early pregnancy?
PEDF from dNK cells limits the lipopolysaccharide (LPS)-induced apoptosis and inflammation of decidual stromal cells (DSCs) to maintain DSCs homoeostasis and immune balance at the maternal-foetal interface during early pregnancy.
dNK cells, which secrete PEDF, play critical roles during pregnancy via a series of key regulators. PEDF, a multifunctional endogenous glycoprotein, exhibits a wide range of biological actions upon angiogenesis, inflammation, metabolic homoeostasis, immunomodulation etc., providing potential clinical applications.
STUDY DESIGN, SIZE, DURATION: Natural killer (NK) cells from decidua and peripheral blood as well as DSCs isolated from normal pregnancy (NP) during the first trimester (6-10 weeks) and the matched patients suffering recurrent miscarriage (RM) were studied. RNA-sequencing analysis of dNK cells was performed to screen for potential key genes involved in RM. The expression of PEDF in dNK cells in NP and RM was examined. A coculture system with LPS-stimulated DSCs and NK cell supernatants derived from NP or RM was established to explore the regulatory mechanisms of PEDF at the maternal-foetal interface.
PARTICIPANTS/MATERIALS, SETTING, METHODS: Peripheral blood and decidual tissues were obtained from women with NP (n = 61) and RM (n = 21). The expression levels of PEDF in NK cells and its receptor (PEDFR) on DSCs were analysed using flow cytometry, western blot and immunohistochemistry. Purified peripheral natural killer (pNK) cells were cocultured with DSCs or trophoblast cells or a combination of both cell types, and PEDF expression in pNK cells was then examined by flow cytometry. DSCs were treated with LPS, an outer-membrane component of Gram-negative bacteria, thereby mimicking an enhanced inflammatory status within decidua, and were cocultured with dNK cell supernatants from NP or RM. In the coculture system, plasmids expressing short hairpin RNA were used to silence PEDFR on DSCs and block the PEDF/PEDFR interaction. Inflammatory cytokines and apoptosis of DSCs treated as described above were assessed by flow cytometry. Western blotting was performed, and the specific signal pathway inhibitors were used to determine downstream PEDF/PEDFR signalling in early decidua.
Markedly higher RNA (P < 0.001) and protein expression of PEDF (P < 0.01) was detected in normal dNK cells when compared with pNK cells. Compared with pNK cells cultured alone, PEDF expression in pNK cells was elevated after coculture with DSCs (P < 0.01) or trophoblast cells (P < 0.001). The increased pro-inflammatory cytokine, tumour necrosis factor-α and apoptosis of DSCs following LPS stimulation were suppressed by recombinant human PEDF (P < 0.001) or the supernatant of dNK cells derived from NP (P < 0.001). However, these effects were somewhat abrogated when the PEDF/PEDFR interaction was blocked with PEDFR short hairpin sRNA (P < 0.01). Furthermore, dNK cell-derived PEDF protected DSCs from LPS-induced inflammation via inhibition of nuclear factor kappa-B activation, while also protecting DSCs from LPS-induced apoptosis via promotion of extracellular signal-regulated kinase expression. Compared with NP, both significantly decreased PEDF RNA (P < 0.001) and protein expression (P < 0.001) in dNK cells, but not in pNK cells (P > 0.05), were detected in women with RM. PEDFR on DSCs was also decreased within RM compared with that within NP (P < 0.001). As a result, dNK cell-mediated anti-inflammation (P < 0.01) and anti-apoptosis (P < 0.05) for protection of LPS-treated DSCs was attenuated in patients suffering from RM.
N/A.
LIMITATIONS, REASONS FOR CAUTION: We cannot exclude the possibility that the differences in amounts of PEDF and its receptor in tissue from NP versus RM women could be caused by the miscarriage event in women with RM. Our experiments only involved human samples investigated in vitro. Experiments in animal models and human study cohorts are still needed to confirm these findings and further clarify the role of PEDF-PEDFR in NP and/or RM.
To the best of our knowledge, this is the first study to demonstrate PEDF expression and function at the maternal-foetal interface in the first trimester, providing further evidence that PEDF exhibits functional diversity and has great potential for clinical application(s). The findings of selectively high expression of PEDF in normal dNK cells and the PEDF-mediated role of dNK cells during NP and RM help to further elucidate the immune mechanisms behind RM.
STUDY FUNDING/COMPETING INTEREST(S): This work was supported by the National Basic Research Programme of China (2017YFC1001403 and 2015CB943300), Nature Science Foundation from National Nature Science Foundation of China (NSFC; 31970859, 81630036, 81501334, 91542116, 31570920, 81490744 and 31171437), the Innovation-oriented Science and Technology Grant from NHC Key Laboratory of Reproduction Regulation (CX2017-2), the Programme of Shanghai Academic/Technology Research Leader (17XD1400900) and the Key Project of Shanghai Basic Research from Shanghai Municipal Science and Technology Commission (STCSM; 12JC1401600). None of the authors has any conflict of interest to declare.
蜕膜自然杀伤 (dNK) 细胞来源的色素上皮衍生因子 (PEDF) 在早孕中的作用是什么?
dNK 细胞来源的 PEDF 可限制脂多糖 (LPS) 诱导的蜕膜基质细胞 (DSC) 凋亡和炎症,以维持早孕时母胎界面的 DSC 稳态和免疫平衡。
分泌 PEDF 的 dNK 细胞通过一系列关键调节因子在妊娠中发挥关键作用。PEDF 是一种多功能内源性糖蛋白,在血管生成、炎症、代谢稳态、免疫调节等方面具有广泛的生物学作用,为潜在的临床应用提供了可能性。
研究设计、规模、持续时间:研究了来自正常妊娠 (NP) 第一孕期 (6-10 周) 和匹配的复发性流产 (RM) 患者的蜕膜和外周血中的 NK 细胞以及从正常妊娠中分离的 DSCs。对 dNK 细胞进行 RNA 测序分析,以筛选与 RM 相关的潜在关键基因。检测 NP 和 RM 中 NK 细胞来源的 PEDF 的表达。建立 LPS 刺激的 DSCs 与来自 NP 或 RM 的 NK 细胞上清液的共培养系统,以探讨 PEDF 在母胎界面的调节机制。
参与者/材料、设置、方法:从 NP (n=61) 和 RM (n=21) 患者中获得外周血和蜕膜组织。通过流式细胞术、Western blot 和免疫组织化学分析 NK 细胞中 PEDF 的表达及其在 DSCs 上的受体 (PEDFR)。然后通过流式细胞术检测纯化的外周自然杀伤 (pNK) 细胞与 DSCs 或滋养层细胞或两者的组合共培养时 pNK 细胞中 PEDF 的表达。用 LPS(革兰氏阴性细菌外膜成分)处理 DSCs,模拟蜕膜内增强的炎症状态,并与 NP 或 RM 的 dNK 细胞上清液共培养。在共培养系统中,使用表达短发夹 RNA 的质粒沉默 DSCs 上的 PEDFR,阻断 PEDF/PEDFR 相互作用。通过流式细胞术评估上述处理的 DSCs 的炎症细胞因子和凋亡。进行 Western blot 并使用特定的信号通路抑制剂确定早期蜕膜中 PEDF/PEDFR 信号通路。
与单独培养的 pNK 细胞相比,正常 dNK 细胞中 PEDF 的 RNA (P<0.001) 和蛋白表达 (P<0.01) 明显更高。与单独培养的 pNK 细胞相比,当与 DSCs (P<0.01) 或滋养层细胞 (P<0.001) 共培养时,pNK 细胞中 PEDF 的表达增加。LPS 刺激后 DSCs 中促炎细胞因子 TNF-α的增加和凋亡被重组人 PEDF (P<0.001) 或来自 NP 的 dNK 细胞上清液 (P<0.001) 抑制。然而,当用 PEDFR 短发夹 RNA 阻断 PEDF/PEDFR 相互作用时,这些作用在某种程度上减弱 (P<0.01)。此外,dNK 细胞来源的 PEDF 通过抑制核因子 kappa-B 激活来保护 DSCs 免受 LPS 诱导的炎症,同时通过促进细胞外信号调节激酶的表达来保护 DSCs 免受 LPS 诱导的凋亡。与 NP 相比,RM 患者的 dNK 细胞中 PEDF 的 RNA (P<0.001) 和蛋白表达 (P<0.001) 均显著降低,而 pNK 细胞中则无显著差异 (P>0.05)。与 NP 相比,RM 患者的 DSCs 上的 PEDFR 也降低 (P<0.001)。因此,在 RM 患者中,dNK 细胞介导的 LPS 处理的 DSCs 的抗炎 (P<0.01) 和抗凋亡 (P<0.05) 作用减弱。
无。
局限性、谨慎的原因:我们不能排除 RM 患者的组织中 NP 与 RM 妇女之间 PEDF 和其受体的量的差异可能是由 RM 中的流产事件引起的。我们的实验仅涉及体外研究的人类样本。仍需要在动物模型和人类研究队列中进行实验,以证实这些发现并进一步阐明 PEDF-PEDFR 在 NP 和/或 RM 中的作用。
据我们所知,这是首次在早孕时在母胎界面证明 PEDF 的表达和功能,进一步证明 PEDF 具有功能多样性,具有很大的临床应用潜力。在正常 dNK 细胞中选择性高表达 PEDF 以及 PEDF 在 NP 和 RM 期间对 dNK 细胞的作用有助于进一步阐明 RM 背后的免疫机制。
研究资金/利益冲突:本工作得到国家重点基础研究发展计划(2017YFC1001403 和 2015CB943300)、国家自然科学基金(31770859、81630036、81501334、91542116、31570920、81490744 和 31171437)、NHC 生殖调控重点实验室创新型科技人才培育计划(CX2017-2)、上海市学术/技术带头人计划(17XD1400900)和上海市科委基础研究重点项目(12JC1401600)的支持。作者均无利益冲突。
