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Protein-Encoding RNA to RNA Information Transfer in Mammalian Cells: RNA-dependent mRNA Amplification. Identification of Chimeric RNA Intermediates and Putative RNA End Products. 哺乳动物细胞中编码RNA到RNA信息传递的蛋白质:RNA依赖性信使核糖核酸扩增。嵌合RNA中间体和推定RNA终产物的鉴定。
Pub Date : 2019-01-01 Epub Date: 2019-08-22
Sophia Rits, Bjorn R Olsen, Vladimir Volloch

Our initial unidirectional understanding of the flow of protein-encoding genetic information, DNA to RNA to protein, a process defined as the "Central Dogma of Molecular Biology" and usually depicted as a downward arrow, was eventually amended to account for the "vertical" information back-flow from RNA to DNA, reverse transcription, and for its "horizontal" side-flow from RNA to RNA, RNA-dependent RNA synthesis, RdRs. These processes, both potentially leading to protein production, were assumed to be strictly virus-specific. However, whereas this presumption might be true for the former, it became apparent that the cellular enzymatic machinery for the later, a conventional RNA-dependent RNA polymerase activity, RdRp, is ubiquitously present and RdRs regularly occurs in eukaryotes. The strongest evidence for the occurrence and functionality of RdRp activity in mammalian cells comes from viruses, such as hepatitis delta virus, HDV, that do not encode RdRp yet undergo a robust RNA replication once inside the host. Eventually, it became clear that RdRp activity, apparently in a non-conventional form, is constitutively present in most, if not in all, mammalian cells. Because such activity was shown to produce short transcripts, because of its apparent involvement in RNA interference phenomena, and because double-stranded RNA is known to trigger cellular responses leading to its degradation, it was generally assumed that its role in mammalian cells is restricted to a regulatory function. However, at the same time, an enzymatic activity capable of generating complete antisense RNA complements of mRNAs was discovered in mammalian cells undergoing terminal differentiation. Moreover, observations of widespread synthesis of antisense RNA initiating at the 3'poly(A) of mRNAs in human cells suggested an extensive cellular utilization of mammalian RdRp. These results led to the development of a model of RdRp-facilitated and antisense RNA-mediated amplification of mammalian mRNA. Here, we report the in vivo detection in cells undergoing terminal erythroid differentiation of the major model-predicted identifiers of such a process, a chimeric double-stranded/pinhead-structured intermediates containing both sense and antisense RNA strands covalently joined in a rigorously predicted and uniquely defined manner. We also report the identification of the putative chimeric RNA end product of mRNA amplification. It is heavily modified, uniformly truncated, yet retains the intact coding region, and terminates with the OH group at both ends; its massive cellular amount is unprecedented for a conventional mRNA transcription product and it translates into polypeptides indistinguishable from the translation product of conventional mRNA. Moreover, we describe the occurrence of the second Tier of mammalian RNA-dependent mRNA amplification, a physiologically occurring, RdRp-driven intracellular PCR process, "iPCR", and report the detection of its distinct RNA end

我们最初对编码遗传信息的蛋白质流动的单向理解,即DNA到RNA到蛋白质的流动,这一过程被定义为“分子生物学的中心法则”,通常被描述为向下的箭头,最终被修改为解释从RNA到DNA的“垂直”信息回流、逆转录,以及从RNA到RNA的“水平”侧流,RNA依赖性RNA合成,RdRs。这些过程都可能导致蛋白质的产生,被认为是严格的病毒特异性过程。然而,尽管这一假设可能适用于前者,但很明显,后者的细胞酶机制,一种传统的RNA依赖性RNA聚合酶活性RdRp,普遍存在,并且RdRs经常发生在真核生物中。哺乳动物细胞中RdRp活性发生和功能的最有力证据来自病毒,如德尔塔肝炎病毒,HDV,它们不编码RdRp,但一旦进入宿主,就会经历强大的RNA复制。最终,很明显,RdRp活性显然是以非常规形式存在于大多数(如果不是全部的话)哺乳动物细胞中。由于这种活性被证明能产生短转录物,因为它明显参与RNA干扰现象,并且已知双链RNA会触发细胞反应导致其降解,因此通常认为它在哺乳动物细胞中的作用仅限于调节功能。然而,与此同时,在经历末端分化的哺乳动物细胞中发现了能够产生mRNA的完全反义RNA互补物的酶活性。此外,在人类细胞中观察到在mRNAs的3′poly(A)处启动的反义RNA的广泛合成,这表明哺乳动物RdRp在细胞中的广泛利用。这些结果导致了RdRp促进和反义RNA介导的哺乳动物mRNA扩增模型的开发。在这里,我们报道了在经历终末期红系分化的细胞中对这种过程的主要模型预测识别物的体内检测,这种过程是一种嵌合的双链/针头结构中间体,含有以严格预测和唯一定义的方式共价连接的正义和反义RNA链。我们还报道了信使核糖核酸扩增的假定嵌合核糖核酸终产物的鉴定。它被严重修饰,均匀截短,但保留了完整的编码区,并以两端的OH基团终止;其巨大的细胞量对于传统的信使核糖核酸转录产物来说是前所未有的,并且它翻译成与传统信使核糖核酸的翻译产物无法区分的多肽。此外,我们描述了哺乳动物RNA依赖性mRNA扩增的第二层的发生,这是一种生理上发生的、RdRp驱动的细胞内PCR过程,“iPCR”,并报告了其不同RNA终产物的检测。哺乳动物的信使核糖核酸扩增是一种特殊的现象,仅限于编程为短生存期的细胞中的末端分化的极端情况,还是一种普遍的生理现象,在Volloch等人的配套文章中得到了回答。Ann Integr Mol Med.2019;1(1):1004。通过检测编码层粘连蛋白α1、β1和γ1链的mRNA的该过程的主要标识符,层粘连蛋白是一种在整个组织和器官发育和稳态过程中大量产生的主要细胞外基质蛋白,也是该现象范围和范围的异常揭示指标。所获得的结果介绍了RNA依赖性mRNA扩增作为一种新的基因组蛋白质编码信息传递模式在哺乳动物细胞中的发生,并将其确立为一种普遍的生理现象。
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引用次数: 0
Protein-Encoding RNA to RNA Information Transfer in Mammalian Cells: RNA-dependent mRNA Amplification. Identification of Chimeric RNA Intermediates and Putative RNA End Products. 哺乳动物细胞中蛋白质编码RNA到RNA的信息传递:RNA依赖的mRNA扩增。嵌合RNA中间体和推测的RNA终产物的鉴定。
Pub Date : 2019-01-01 DOI: 10.33597/aimm.01-1003
S. Rits, B. Olsen, V. Volloch
Our initial unidirectional understanding of the flow of protein-encoding genetic information, DNA to RNA to protein, a process defined as the "Central Dogma of Molecular Biology" and usually depicted as a downward arrow, was eventually amended to account for the "vertical" information back-flow from RNA to DNA, reverse transcription, and for its "horizontal" side-flow from RNA to RNA, RNA-dependent RNA synthesis, RdRs. These processes, both potentially leading to protein production, were assumed to be strictly virus-specific. However, whereas this presumption might be true for the former, it became apparent that the cellular enzymatic machinery for the later, a conventional RNA-dependent RNA polymerase activity, RdRp, is ubiquitously present and RdRs regularly occurs in eukaryotes. The strongest evidence for the occurrence and functionality of RdRp activity in mammalian cells comes from viruses, such as hepatitis delta virus, HDV, that do not encode RdRp yet undergo a robust RNA replication once inside the host. Eventually, it became clear that RdRp activity, apparently in a non-conventional form, is constitutively present in most, if not in all, mammalian cells. Because such activity was shown to produce short transcripts, because of its apparent involvement in RNA interference phenomena, and because double-stranded RNA is known to trigger cellular responses leading to its degradation, it was generally assumed that its role in mammalian cells is restricted to a regulatory function. However, at the same time, an enzymatic activity capable of generating complete antisense RNA complements of mRNAs was discovered in mammalian cells undergoing terminal differentiation. Moreover, observations of widespread synthesis of antisense RNA initiating at the 3'poly(A) of mRNAs in human cells suggested an extensive cellular utilization of mammalian RdRp. These results led to the development of a model of RdRp-facilitated and antisense RNA-mediated amplification of mammalian mRNA. Here, we report the in vivo detection in cells undergoing terminal erythroid differentiation of the major model-predicted identifiers of such a process, a chimeric double-stranded/pinhead-structured intermediates containing both sense and antisense RNA strands covalently joined in a rigorously predicted and uniquely defined manner. We also report the identification of the putative chimeric RNA end product of mRNA amplification. It is heavily modified, uniformly truncated, yet retains the intact coding region, and terminates with the OH group at both ends; its massive cellular amount is unprecedented for a conventional mRNA transcription product and it translates into polypeptides indistinguishable from the translation product of conventional mRNA. Moreover, we describe the occurrence of the second Tier of mammalian RNA-dependent mRNA amplification, a physiologically occurring, RdRp-driven intracellular PCR process, "iPCR", and report the detection of its distinct RNA end products. Whe
我们最初对蛋白质编码遗传信息流动的单向理解,即DNA到RNA到蛋白质,这一过程被定义为“分子生物学的中心法则”,通常被描述为向下的箭头,最终被修正为解释从RNA到DNA的“垂直”信息倒流,逆转录,以及从RNA到RNA的“水平”侧流,RNA依赖RNA合成,RdRs。这些过程,都可能导致蛋白质的产生,被认为是严格的病毒特异性的。然而,尽管这一假设可能对前者是正确的,但很明显,后者的细胞酶机制,传统的RNA依赖的RNA聚合酶活性,RdRp,是普遍存在的,并且RdRp在真核生物中有规律地发生。哺乳动物细胞中RdRp活性的发生和功能的最有力证据来自病毒,如丁型肝炎病毒(HDV),它们不编码RdRp,但一旦进入宿主,就会进行强大的RNA复制。最终,我们发现RdRp活性(显然是以非常规的形式)存在于大多数(如果不是全部的话)哺乳动物细胞中。由于这种活性被证明产生短转录本,由于其明显参与RNA干扰现象,并且由于双链RNA已知会触发导致其降解的细胞反应,因此通常认为其在哺乳动物细胞中的作用仅限于调节功能。然而,与此同时,在处于终末分化的哺乳动物细胞中发现了一种能够产生mrna的完全反义RNA补体的酶活性。此外,观察到反义RNA在人类细胞中广泛合成,起始于mrna的3'poly(A),这表明哺乳动物RdRp在细胞中被广泛利用。这些结果导致了rdrp促进和反义rna介导的哺乳动物mRNA扩增模型的建立。在这里,我们报告了在经历终末红系分化的细胞中对这一过程的主要模型预测标识符的体内检测,这是一种嵌合双链/针尖结构的中间体,包含以严格预测和独特定义的方式共价连接的正义和反义RNA链。我们还报道了mRNA扩增的推定嵌合RNA最终产物的鉴定。它被大量修饰,均匀截断,但保留完整的编码区,并在两端以OH基团终止;其巨大的细胞数量对于传统的mRNA转录产物来说是前所未有的,并且它可以翻译成与传统mRNA翻译产物难以区分的多肽。此外,我们描述了哺乳动物RNA依赖mRNA扩增的第二层的发生,这是一种生理上发生的,rdrp驱动的细胞内PCR过程,“iPCR”,并报告了其不同RNA最终产物的检测。哺乳动物mRNA扩增是一种特殊的现象,仅限于细胞在极短的生存时间内进行终末分化的极端情况下,还是一种普遍的生理现象,这一问题在Volloch等人的文章中得到了解答。中国生物医学工程学报,2019;31(1):391 - 391。通过检测编码层粘连蛋白α1, β1和γ1链的mRNA的主要标识符,层粘连蛋白是一种主要的细胞外基质蛋白,在整个组织和器官发育和稳态中大量产生,是该现象的范围和范围的异常揭示指标。这些结果介绍了rna依赖性mRNA扩增作为一种基因组蛋白编码信息传递的新模式在哺乳动物细胞中的发生,并将其确立为一种普遍的生理现象。
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引用次数: 12
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Annals of integrative molecular medicine
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