A Transient Mystery: Nucleolar Channel Systems.

Q4 Biochemistry, Genetics and Molecular Biology Results and Problems in Cell Differentiation Pub Date : 2022-01-01 DOI:10.1007/978-3-031-06573-6_20
Claudia C Preston, Ashley C Stoddard, Randolph S Faustino
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Abstract

The nucleus is a complex organelle with functions beyond being a simple repository for genomic material. For example, its actions in biomechanical sensing, protein synthesis, and epigenomic regulation showcase how the nucleus integrates multiple signaling modalities to intricately regulate gene expression. This innate dynamism is underscored by subnuclear components that facilitate these roles, with elements of the nucleoskeleton, phase-separated nuclear bodies, and chromatin safeguarding by nuclear envelope proteins providing examples of this functional diversity. Among these, one of the lesser characterized nuclear organelles is the nucleolar channel system (NCS), first reported several decades ago in human endometrial biopsies. This tubular structure, believed to be derived from the inner nuclear membrane of the nuclear envelope, was first observed in secretory endometrial cells during a specific phase of the menstrual cycle. Reported as a consistent, yet transient, nuclear organelle, current interpretations of existing data suggest that it serves as a marker of a window for optimal implantation. In spite of this available data, the NCS remains incompletely characterized structurally and functionally, due in part to its transient spatial and temporal expression. As a further complication, evidence exists showing NCS expression in fetal tissue, suggesting that it may not act exclusively as a marker of uterine receptivity, but rather as a hormone sensor sensitive to estrogen and progesterone ratios. To gain a better understanding of the NCS, current technologies can be applied to profile rare cell populations or capture transient structural dynamics, for example, at a level of sensitivity and resolution not previously possible. Moving forward, advanced characterization of the NCS will shed light on an uncharacterized aspect of reproductive physiology, with the potential to refine assisted reproductive techniques.

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一个短暂的谜团:核仁通道系统。
细胞核是一个复杂的细胞器,其功能不仅仅是基因组物质的简单储存库。例如,它在生物力学传感、蛋白质合成和表观基因组调控中的作用展示了细胞核如何整合多种信号传导方式来复杂地调节基因表达。促进这些作用的亚核成分强调了这种内在的动力,核骨架的元素、相分离的核体和核包膜蛋白保护的染色质提供了这种功能多样性的例子。其中,核核通道系统(NCS)是较不常见的核细胞器之一,几十年前在人类子宫内膜活检中首次报道。这种管状结构被认为来源于核膜的内核膜,在月经周期的一个特定阶段,在分泌性子宫内膜细胞中首次观察到。据报道,它是一种稳定但短暂的核细胞器,目前对现有数据的解释表明,它可以作为最佳植入窗口的标志。尽管有这些可用的数据,但由于其短暂的空间和时间表达,NCS在结构和功能上仍然不完整。作为进一步的并发症,有证据表明NCS在胎儿组织中表达,这表明它可能不仅仅作为子宫容受性的标志,而是作为对雌激素和孕激素比例敏感的激素传感器。为了更好地理解NCS,目前的技术可以应用于绘制罕见细胞群或捕获瞬态结构动力学,例如,在以前不可能达到的灵敏度和分辨率水平上。展望未来,NCS的高级特征将揭示生殖生理学的一个未特征方面,具有改进辅助生殖技术的潜力。
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来源期刊
Results and Problems in Cell Differentiation
Results and Problems in Cell Differentiation Biochemistry, Genetics and Molecular Biology-Developmental Biology
CiteScore
1.90
自引率
0.00%
发文量
21
期刊介绍: Results and Problems in Cell Differentiation is an up-to-date book series that presents and explores selected questions of cell and developmental biology. Each volume focuses on a single, well-defined topic. Reviews address basic questions and phenomena, but also provide concise information on the most recent advances. Together, the volumes provide a valuable overview of this exciting and dynamically expanding field.
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