Maintenance of tissue-specific stem cells is vital for organ homeostasis and organismal longevity. Hematopoietic stem cells (HSCs) are the most primitive cell type in the hematopoietic system. They divide asymmetrically and give rise to daughter cells with HSC identity (self-renewal) and progenitor progenies (differentiation), which further proliferate and differentiate into full hematopoietic lineages. Mammalian ageing process is accompanied with abnormalities in the HSC self-renewal and differentiation. Transcriptional changes and epigenetic modulations have been implicated as the key regulators in HSC ageing process. The DNA damage response (DDR) in the cells involves an orchestrated signaling pathway, consisting of cell cycle regulation, cell death and senescence, transcriptional regulation, as well as chromatin remodeling. Recent studies employ-ing DNA repair-deficient mouse models indicate that DDR could intrinsically and extrinsically reg-ulate HSC maintenance and play important roles in tissue homeostasis of the hematopoietic system. In this review, we summarize the current understanding of how the DDR determines the HSC fates and finally contributes to organismal ageing.

Nonsense-mediated mRNA decay(NMD)is a highly conserved post-transcriptional regulatory mechanism in eukaryotic cells.NMD can recognize and degrade abnormal transcripts con-taining premature termination codons(PTC)to pre-vent the translation of C-terminal truncated pro-teins.Furthermore,NMD could degrade a subset of normal gene transcripts and thus fine-tune gene ex-pression.NMD is essential for cell fate determina-tion,stress response,as well as animal develop-ment.In this review,we briefly discussed the func-tional and molecular mechanisms of NMD pathway activation and inhibition in tumorigenesis,cancer progression and therapy.Current studies indicate that NMD factor mutations can lead to a variety of human tumors.Interestingly,inhibition of NMD fac-tors can activate DNA damage response and inhibit the expression of oncogenic factors,thereby killing cancer cells.This review may provide new perspec-tives for the biological mechanism and therapeutic strategy of human tumors.

无义介导的信使RNA（mRNA）降解途径（nonsense-mediated mRNA decay，简称为NMD)是真核生物细胞内一种重要的基因转录后表达调控机制，它积极参与一系列细胞生理和生化过程，控制细胞命运和生命体的组织稳态。NMD的缺陷会导致人类疾病，如神经发育障碍、肿瘤发生和自身免疫疾病等。UPF3 (Up-frameshift protein 3)是一个核心的NMD因子，它最早在酵母中被发现。UPF3A和UPF3B是UPF3在生物进化到脊椎动物阶段出现的两个旁系同源物，在NMD中具有激活或抑制的作用。以往研究发现，UPF3B蛋白几乎在所有哺乳动物器官中均有表达，而UPF3A蛋白在除睾丸外的大多数哺乳动物组织中难以被检测到。解释这一现象的假说为：在NMD途径中，UPF3B具有比UPF3A更高的竞争性结合UPF2的能力，UPF3B和UPF2的结合促使UPF3A成为游离状态，而游离的UPF3A蛋白不稳定且易被降解。此假说提示UPF3A和UPF3B在NMD中存在拮抗作用。在本研究中，我们重新定量评估了UPF3A和UPF3B在野生型成年雄性和雌性小鼠的9个主要组织和生殖器官中的mRNA和蛋白表达，结果证实UPF3A在雄性生殖细胞中表达量最高。令人惊讶的是，我们发现在包括大脑和胸腺在内的大多数组织中，UPF3A与UPF3B的蛋白水平相当，而在小鼠脾、肺组织中，UPF3A表达高于UPF3B。公共基因表达数据进一步支持了上述发现。因此，我们的研究表明了UPF3A是小鼠组织中普遍表达的NMD因子。同时，该研究结果推测：在生理条件下，UPF3A和UPF3B蛋白之间不存在竞争抑制，且UPF3A在多种哺乳动物组织的稳态中发挥重要作用。
Animals ; Humans ; Mice ; HeLa Cells ; Nonsense Mediated mRNA Decay ; RNA-Binding Proteins/genetics*