Effect of polyamines on translation fidelity <i>in vivo</i>

McMurry, Laura M.; Algranati, Israel D.

doi:10.1111/j.1432-1033.1986.tb09502.x

Cited by 33 publications

(20 citation statements)

References 53 publications

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“…In both bacterial and wheat germ extracts, increasing the concentration of spermidine from 1 to 3 mM decreased the rate of misincorporation of leucine in place of phenylalanine by ribosomes programmed with poly(U) mRNA-encoding polyphenylalanine (53,54). Consistent with these findings, the relatively high level of misreading observed in E. coli strains that were defective or auxotrophic for polyamine synthesis was partially suppressed by addition of putrescine to the media (55). In contrast to these studies linking increased polyamines to enhanced fidelity during translation elongation, high polyamines were linked to stop codon readthrough on the ␤-globin mRNA in rabbit reticulocyte lysate (56).…”

Section: Impacts Of Polyamines On Translational Fidelitysupporting

confidence: 63%

Roles of polyamines in translation

Dever

Ivanov

2018

Journal of Biological Chemistry

105

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Polyamines are organic polycations that bind to a variety of cellular molecules, including nucleic acids. Within cells, polyamines contribute to both the efficiency and fidelity of protein synthesis. In addition to directly acting on the translation apparatus to stimulate protein synthesis, the polyamine spermidine serves as a precursor for the essential post-translational modification of the eukaryotic translation factor 5A (eIF5A), which is required for synthesis of proteins containing problematic amino acid sequence motifs, including polyproline tracts, and for termination of translation. The impact of polyamines on translation is highlighted by autoregulation of the translation of mRNAs encoding key metabolic and regulatory proteins in the polyamine biosynthesis pathway, including S-adenosylmethionine decarboxylase (AdoMetDC), antizyme (OAZ), and antizyme inhibitor 1 (AZIN1). Here, we highlight the roles of polyamines in general translation and also in the translational regulation of polyamine biosynthesis.Because of their cationic properties, polyamines bind to negatively charged molecules in cells. Nucleic acids, including both DNA and RNA, are prominent binding sites for polyamines with nearly 90% of the spermidine in Escherichia coli cells bound to RNA (1). A substantial fraction (ϳ15%) of the polyamines in E. coli are stably associated with ribosomes (2). Polyamines stimulate general protein synthesis and also impact the fidelity of translation. The importance of polyamines to translation is highlighted by the mRNA-specific translational control mechanisms that link polyamine levels to the synthesis of key polyamine biosynthetic enzymes and their regulators. In this Minireview, we will highlight the roles of polyamines in general translation and in the translational regulation of polyamine biosynthesis. In honor of Herb Tabor, we will also highlight his contributions to this area of polyamine research.3 The abbreviations used are: A,

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Section: Impacts Of Polyamines On Translational Fidelitysupporting

confidence: 63%

Roles of polyamines in translation

Dever

Ivanov

2018

Journal of Biological Chemistry

105

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“…They regulate the fidelity of aminoacylation; increasing concentrations of polyamines reduce the frequency of misacylation, especially in the absence of Mg 2ϩ (116). This effect might explain why increasing the concentration of polyamines increases the fidelity of protein synthesis in vitro (88) and in vivo (132). However, the effect of polyamines on translation appears to be more complex, affecting the conformation of aminoacyl-tRNAs and thus the efficiency and accuracy of codon-anticodon recognition (reference 145 and references therein).…”

Section: The Rat Ornithine Decarboxylase Antizyme Genementioning

confidence: 99%

Programmed Translational Frameshifting

1996

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▪ Abstract Errors that alter the reading frame occur extremely rarely during translation, yet some genes have evolved sequences that efficiently induce frameshifting. These sequences, termed programmed frameshift sites, manipulate the translational apparatus to promote non-canonical decoding. Frameshifts are mechanistically diverse. Most cause a −1 shift of frames; the first such site was discovered in a metazoan retrovirus, but they are now known to be dispersed quite widely among evolutionarily diverse species. +1 frameshift sites are much less common, but again dispersed widely. The rarest form are the translational hop sites which program the ribosome to bypass a region of several dozen nucleotides. Each of these types of events are stimulated by distinct mechanisms. All of the events share a common phenomenology in which the programmed frameshift site causes the ribosome to pause during elongation so that the kinetically unfavorable alternative decoding event can occur. During this pause most frameshifts occur because one or more ribosome-bound tRNAs slip between cognate or near-cognate codons. However, even this generalization is not entirely consistent, since some frameshifts occur without slippage. Because of their similarity to rarer translational errors, programmed frameshift sites provide a tool with which to probe the mechanism of frame maintenance.

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“…The same was true for the N α ,N ω -bismethyl derivatives; the strongest hydrogen bonds between the polyamine and tRNA were those formed by the central nitrogens (N 4 and N 9 ), independent of the alkyl substituent (methyl or ethyl) present at the terminal nitrogen groups. Binding of polyamines to tRNA has been shown to be relevant to the fidelity of the translation process [16][17][18][19] , as well as to codon-anticodon recognition and ribosomal binding [20][21] . Polyamines also stimulate aminoacylation in general and their effects on the structure of tRNA compelled attention to the possible role of these compounds for protein synthesis 22 .…”

Section: Introductionmentioning

confidence: 99%

Regioselective binding of spermine, N¹,N12-bismethylspermine, and N¹,N12-bisethylspermine to tRNA Phe as revealed by 750 MHz ¹H-NMR and its possible correlation with cell cycling and cytotoxicity

Frydman¹,

Westler²,

Valasinas³

et al. 1999

J. Braz. Chem. Soc.

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A58 e U50-A64. Esta regiosseletividade de ligação das três poliaminas ao tRNA foi correlacionada com seus efeitos biológicos no crescimento celular. Usando células de câncer de melanoma humano (MALME-3M), foi encontrado que SPM e BMS não tem efeito e é citostático, respectivamente, enquanto que BES é claramente citotóxica. Esta última poliamina também afeta o ciclo celular e, contrário ao comportamento de SPM e BMS, acarreta a uma clara parada do ciclo celular G1 /S. A58 and U50-A64. This regioselectivity in the binding of the three polyamines to tRNA was correlated with their biological effects on cell growth. Using human melanoma cancer cells (MALME-3M), we found that SPM and BMS were without effect and cytostatic, respectively, while BES was distinctly cytotoxic. The latter also affected cell cycling and, at variance with SPM and BMS, lead to a distinct G1/S cell cycle arrest.

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Effect of polyamines on translation fidelity in vivo

Cited by 33 publications

References 53 publications

Roles of polyamines in translation

Roles of polyamines in translation

Programmed Translational Frameshifting

Regioselective binding of spermine, N¹,N12-bismethylspermine, and N¹,N12-bisethylspermine to tRNA Phe as revealed by 750 MHz ¹H-NMR and its possible correlation with cell cycling and cytotoxicity

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