Translational regulation by mRNA/protein interactions in eukaryotic cells: Ferritin and beyond

The expression of certain eukaryotic genes is – at least in part – controlled at the level of mRNA translation. The step of translational initiation represents the primary target for regulation. The regulation of the intracellular iron storage protein ferritin in response to iron levels provides a good example of translational control by a reversible RNA/protein interaction in the 5' untranslated region of an mRNA. We consider mechanisms by which mRNA/protein interactions may impede translation initiation and discuss recent data suggesting that the ferritin example may represent the ‘tip of the iceberg’ of a more general theme for translational control.     

古菌蛋白激酶的研究进展

磷酸化是蛋白质翻译后修饰(post-translational modification)的主要方式,可由蛋白激酶、磷酸转移酶、磷酸化酶等多种方式催化进行。其中,由蛋白激酶(protein kinases)/磷酸酶(protein phosphatases)介导的可逆的蛋白磷酸化是细胞中信号转导的重要机制,在DNA复制、转录、蛋白质翻译、DNA损伤修复等生命过程中起广泛的调节作用。目前,古菌中蛋白激酶的研究尚属于初期阶段。虽然磷酸化蛋白质组学研究表明,古菌中存在大量的磷酸化蛋白质,但是我们对其具体催化作用的酶及调控机制尚不清楚。本文总结了古菌中已报道的蛋白激酶所参与的生命过程,包括古菌的DNA代谢、细胞代谢、细胞周期和运动机制等四个方面,并对今后的研究提出展望。     

A hypoxia-controlled cap-dependent to cap-independent translation switch in breast cancer

Translational regulation is critical in cancer development and progression. Translation sustains tumor growth and development of a tumor vasculature, a process known as angiogenesis, which is activated by hypoxia. Here we first demonstrate that a majority of large advanced breast cancers overexpress translation regulatory protein 4E-BP1 and initiation factor eIF4G. Using model animal and cell studies, we then show that overexpressed 4E-BP1 and eIF4G orchestrate a hypoxia-activated switch from cap-dependent to cap-independent mRNA translation that promotes increased tumor angiogenesis and growth at the level of selective mRNA translation. Elevated levels of 4E-BP1 trigger hypoxia inhibition of cap-dependent mRNA translation at high-oxygen levels and, with eIF4G, increase selective translation of mRNAs containing internal ribosome entry sites (IRESs) that include key proangiogenic, hypoxia, and survival mRNAs. The switch from cap-dependent to cap-independent mRNA translation facilitates tumor angiogenesis and hypoxia responses in animal models.     

长链非编码RNA的免疫调节机制研究进展

真核生物的基因表达受多个层面调控,包括染色体水平、DNA水平、转录水平和转录后水平的调控等.长链非编码RNA(lnc RNA)是一类转录本超过200 nt的非编码RNA,其对基因表达的调控涉及上述各个层面,如组蛋白修饰、DNA甲基化的调控、转录的促进和抑制、m RNA的剪辑及对转录因子的调控等.其作用方式复杂多样,可与DNA、mRNA和蛋白质等相互作用而发挥调节作用.LncRNA保守性较差,但其表达却有较高的细胞、组织和分化阶段特异性.免疫系统的发育和分化受到精密的调控,且具有较高的阶段性和特异性.因此研究lnc RNA的功能及作用机制,免疫系统是较好的选择,这能促进我们对免疫调控的理解,为免疫性疾病的治疗提供新的思路和方法.本文主要介绍lnc RNA的分类和lnc RNA作用的一般分子机制,及其对T细胞、B细胞、固有免疫细胞和炎症因子的分子调控机制及其进展.     

microRNA在非酒精性脂肪性肝病中的作用

microRNA(miRNA)是一类长度约为22个核苷酸的内源性非编码小分子RNA,通过影响靶mRNA的稳定性或抑制其翻译,从而对基因进行转录后水平的调控。研究发现,一些miRNA在非酒精性脂肪性肝病患者中出现差异性表达,这些差异性表达有多种功能,包括调节脂质和糖代谢,参与折叠蛋白反应、内质网应激、氧化应激、细胞分化、炎性反应及细胞凋亡。此文就miRNA在非酒精性脂肪性肝病病程中的潜在重要作用进行概述。     

Drosha mediates destabilization of Lin28 mRNA targets

Lin28 plays important roles in development, stem cell maintenance, oncogenesis and metabolism. As an RNA-binding protein, it blocks the biogenesis primarily of let-7 family miRNAs and also promotes translation of a cohort of mRNAs involved in cell growth, metabolism and pluripotency, likely through recognition of distinct sequence and structural motifs within mRNAs. Here, we show that one such motif, shared by multiple Lin28-responsive elements (LREs) present in Lin28 mRNA targets also participates in a Drosha-dependent regulation and may contribute to destabilization of its cognate mRNAs. We further show that the same mutations in the LREs known to abolish Lin28 binding and stimulation of translation also abrogate Drosha-dependent mRNA destabilization, and that this effect is independent of miRNAs, uncovering a previously unsuspected coupling between Drosha-dependent destabilization and Lin28-mediated regulation. Thus, Lin28-dependent stimulation of translation of target mRNAs may, in part, serve to compensate for their intrinsic instability, thereby ensuring optimal levels of expression of genes critical for cell viability, metabolism and pluripotency.     

Drosha mediates destabilization of Lin28 mRNA targets

Lin28 plays important roles in development, stem cell maintenance, oncogenesis and metabolism. As an RNA-binding protein, it blocks the biogenesis primarily of let-7 family miRNAs and also promotes translation of a cohort of mRNAs involved in cell growth, metabolism and pluripotency, likely through recognition of distinct sequence and structural motifs within mRNAs. Here, we show that one such motif, shared by multiple Lin28-responsive elements (LREs) present in Lin28 mRNA targets also participates in a Drosha-dependent regulation and may contribute to destabilization of its cognate mRNAs. We further show that the same mutations in the LREs known to abolish Lin28 binding and stimulation of translation also abrogate Drosha-dependent mRNA destabilization, and that this effect is independent of miRNAs, uncovering a previously unsuspected coupling between Drosha-dependent destabilization and Lin28-mediated regulation. Thus, Lin28-dependent stimulation of translation of target mRNAs may, in part, serve to compensate for their intrinsic instability, thereby ensuring optimal levels of expression of genes critical for cell viability, metabolism and pluripotency.     

What Happens Inside Lentivirus or Influenza Virus Infected Cells: Insights into Regulation of Cellular and Viral Protein Synthesis

Efficient manipulation of the regulatory mechanisms controlling host cell gene expression provides the means for productive infection by animal viruses. Upon infecting the host cell, viruses must: (i) bypass the cellular antiviral defense mechanisms to prevent the translational blocks imposed by the interferon pathway; and (ii) effectively “hijack” the host protein synthetic machinery into mass production of virion protein components. The multicomponent regulatory nature of cellular gene expression has provided the means of selecting for a diverse range of mechanisms utilized by animal viruses to ensure that replication efficiency is maintained throughout the virus life cycle. One important research component of the careful examination of gene regulation is those studies that focus on elucidating the mechanisms by which viruses control mRNA translation during host cell infection. Much of the work in our laboratory has focused on elucidating the strategies by which human immunodeficiency virus type 1 and influenza virus regulate protein synthesis during infection. Here we describe the ways in which these two distinctly different RNA viruses ensure the selective and efficient translation of their viral mRNAs in infected cells. These strategies include circumvention of the deleterious effects associated with activation of the interferon-induced protein kinase, PKR. Herein we describe our methodologies designed to elucidate the translational regulation in cells infected by these viruses. We conclude with a brief summary of new directions, utilizing these methods, taken toward understanding the translational control mechanisms imposed by these viral systems, and how our studies of virally infected cells have allowed us to identify growth-regulating components of normal, uninfected cells.     

利用cDNA-AFLP技术分析龙眼子叶胚基因表达差异

分别提取'红核子'龙眼(Dimdcarpus longan Lour.)谢花后35 d(早期)和50 d(晚期)子叶胚RNA,建立cDNA-AFLP分析体系,获得指纹图谱.对41个差异片段回收克隆和序列分析,表明其中21个与已知功能基因具有高度同源性,这些基因的功能主要涉及侧牛器官的离轴极性、糖酵解、能最代谢、离子转运、细胞壁伸长、细胞周期调控、RNA转录、RNA翻译和调控、蛋白磷酸化调控和降解、信号转导等;其余片段与已知基因的同源性较低或没有.     

Control of cell metabolism by the epidermal growth factor receptor

The epidermal growth factor receptor (EGFR) triggers the activation of many intracellular signals that control cell proliferation, growth, survival, migration, and differentiation. Given its wide expression, EGFR has many functions in development and tissue homeostasis. Some of the cellular outcomes of EGFR signaling involve alterations of specific aspects of cellular metabolism, and alterations of cell metabolism are emerging as driving influences in many physiological and pathophysiological contexts. Here we review the mechanisms by which EGFR regulates cell metabolism, including by modulation of gene expression and protein function leading to control of glucose uptake, glycolysis, biosynthetic pathways branching from glucose metabolism, amino acid metabolism, lipogenesis, and mitochondrial function. We further examine how this regulation of cell metabolism by EGFR may contribute to cell proliferation and differentiation and how EGFR-driven control of metabolism can impact certain diseases and therapy outcomes.