Effects of post-transcriptional base modifications on the site-specific function of transfer RNA in eukaryote translation

Plant hormones increase efficiency of reprogramming mouse somatic cells to induced pluripotent stem cells and reduce tumorigenicity

Reprogramming of somatic cells into induced pluripotent stem (iPS) cells by defined pluripotency and self-renewal factors has taken stem cell technology to the forefront of regenerative medicine. However, a number of challenges remain in the field including efficient protocols and the threat of cancer. Reprogramming of plant somatic cells to plant embryonic stem cells using a combination of two plant hormones was discovered in 1957 and has been a routine university laboratory practical for over 30 years. The plant hormones responsible for cell reprogramming to pluripotency, indole-3-acetic acid (IAA) and isopentenyl adenosine (IPA), are present in human cells, leading to the exciting possibility that plant hormones might reprogram mammalian cells without genetic factors. We found that plant hormones on their own could not reprogram mammalian cells but increase the efficiency of the early formation of iPS cells combined with three defined genetic factors during the first 3 weeks of reprogramming by accelerating the cell cycle and regulating pluripotency genes. Moreover, the cytokinin IPA, a known human anticancer agent, reduced the threat of cancer of iPS cell in vitro by regulating key cancer and stem cell-related genes, most notably c-Myc and Igf-1. In conclusion, the plant hormones, auxin and cytokinin, are new small chemicals useful for enhancing early reprogramming efficiency of mammalian cells and reducing the threat of cancer from iPS cells. These findings suggest a novel role for plant hormones in the biology of mammalian cell plasticity.

Ribosomal frameshifting in response to hypomodified tRNAs in Xenopus oocytes

We used Xenopus oocytes as an intracellular system to study ribosomal frameshifting. Microinjection of oocytes with a construct encoding the naturally occurring UUU or AAC codon at the frameshift site demonstrated that the level of frameshifting was similar or lower than found normally in retroviral frameshifting in mammalian cells, suggesting that oocytes are a reliable system to study this event. Phenylalanine (Phe) or asparagine (Asn) tRNAs with and without the highly modified wyebutoxine (Y) or queuosine (Q) base, respectively, were microinjected to assess their ability to promote frameshifting. tRNAPhe+Y inhibited the level of frameshifting, while tRNAPhe-Y promoted frameshifting providing evidence that the hypomodified form does not act only to enhance frameshifting, but is an essential requirement. Both tRNAAsn+Q and tRNAAsn-Q were used indiscriminately in frameshifting, whether the frameshift site contained the wild-type AAC, or the mutant AAU codon, suggesting that Q base modification status does not influence this process.

Decoding the genome: a modified view

Transfer RNA's role in decoding the genome is critical to the accuracy and efficiency of protein synthesis. Though modified nucleosides were identified in RNA 50 years ago, only recently has their importance to tRNA's ability to decode cognate and wobble codons become apparent. RNA modifications are ubiquitous. To date, some 100 different posttranslational modifications have been identified. Modifications of tRNA are the most extensively investigated; however, many other RNAs have modified nucleosides. The modifications that occur at the first, or wobble position, of tRNA's anticodon and those 3'-adjacent to the anticodon are of particular interest. The tRNAs most affected by individual and combinations of modifications respond to codons in mixed codon boxes where distinction of the third codon base is important for discriminating between the correct cognate or wobble codons and the incorrect near-cognate codons (e.g. AAA/G for lysine versus AAU/C asparagine). In contrast, other modifications expand wobble codon recognition, such as U*U base pairing, for tRNAs that respond to multiple codons of a 4-fold degenerate codon box (e.g. GUU/A/C/G for valine). Whether restricting codon recognition, expanding wobble, enabling translocation, or maintaining the messenger RNA, reading frame modifications appear to reduce anticodon loop dynamics to that accepted by the ribosome. Therefore, we suggest that anticodon stem and loop domain nucleoside modifications allow a limited number of tRNAs to accurately and efficiently decode the 61 amino acid codons by selectively restricting some anticodon-codon interactions and expanding others.

Conformational preferences of the base substituent in hypermodified nucleotide queuosine 5'-monophosphate 'pQ' and protonated variant 'pQH+'

Conformational preferences of the base substituent in hypermodified nucleotide queuosine 5'-monophosphate 'pQ' and its protonated form 'pQH+' have been studied using quantum chemical Perturbative Configuration Interaction with Localized Orbitals PCILO method. The salient points have also been examined using molecular mechanics force field MMFF, parameterized modified neglect of differential overlap PM3 and Hartree Fock-Density Functional Theory HF DFT (pBP/DN*) approaches. Aqueous solvation of pQ and pQH+ has also been studied using molecular dynamics simulations. Consistent with the observed crystal structure, in isolated protonated form pQH+, the quaternary amine HN(13)(+)H, of the sidechain having 7-aminomethyl linkage, hydrogen bonds with the carbonyl oxygen O(10) of the base. However, N(13)H-O(10) hydrogen bonding is not preferred for unprotonated pQ, whether isolated or hydrated. Interaction between the 5'-phosphate and the 7-aminomethyl group is more likely for isolated pQ. The cyclopentenediol hydroxyl group O4"H may hydrogen bond with the O(10) in isolated pQ as well as in pQH+. The O4"H may hydrogen bond with the 5'-phosphate as well. The presence of -CH2-NH- and O"H groups in pQ and pQH+ allows interesting possibilities for intranucleotide hydrogen bonds and interactions across the anticodon loop. Simultaneous hydrogen bonds O2P-HN(13)+H-O(10) are indicated for hydrated pQH+. Unlike weak involvement of O4"H, these interactions also persist in hydrated pQH+ and may much reduce backbone flexibility. Resulting sub-optimal Q:C base pairing leads to unbiased reading of U or C as the third codon letter. Cyclopentenediol hydroxyl groups may interact with other biomolecules, allowing specific recognition. Prospective pQ(34) and pQ(34)H+ sites for codon-anticodon base pairing remain unhindered, but non canonical Q:G base pairing (amber-suppression) is ruled out.

1-Methylguanosine in place of Y base at position 37 in phenylalanine tRNA is responsible for its shiftiness in retroviral ribosomal frameshifting

Many mammalian retroviruses express their protease and polymerase by ribosomal frameshifting. It was originally proposed that a specialized shifty tRNA promotes the frameshift event. We previously observed that phenylalanine tRNA(Phe) lacking the highly modified wybutoxosine (Y) base on the 3' side of its anticodon stimulated frameshifting, demonstrating that this tRNA is shifty. We now report the shifty tRNA(Phe) contains 1-methylguanosine (m(1)G) in place of Y and that the m(1)G form from rabbit reticulocytes stimulates frameshifting more efficiently than its m(1)G-containing counterpart from mouse neuroblastoma cells. The latter tRNA contains unmodified C and G nucleosides at positions 32 and 34, respectively, while the former tRNA contains the analogous 2'-O-methylated nucleosides at these positions. The data suggest that not only does the loss of a highly modified base from the 3' side of the anticodon render tRNA(Phe) shifty, but the modification status of the entire anticodon loop contributes to the degree of shiftiness. Possible biological consequences of these findings are discussed.

Yeast asparagine (Asn) tRNA without Q base promotes eukaryotic frameshifting more efficiently than mammalian Asn tRNAs with or without Q base

In this study, we compare the efficiency of Asn tRNA from mammalian sources with and without the highly modified queuosine (Q) base in the wobble position of its anticodon and Asn tRNA from yeast, which naturally lacks Q base, to promote frameshifting. Interestingly, no differences in the ability of the two mammalian Asn tRNAs to promote frameshifting were observed, while yeast tRNA(ASn)(-Q) promoted frameshifting more efficiently than its mammalian counterparts in both rabbit reticulocyte lysates and wheat germ extracts. The shiftability of yeast Asn tRNA is therefore not due, or at least not completely, to the lack of Q base and most likely the shiftiness resides in structural differences elsewhere in the molecule. However, we cannot absolutely rule out a role of Q base in frameshifting as wheat germ extracts and a lysate depleted of most of its tRNA and supplemented with calf liver tRNA contain both Asn tRNA with or without Q base.

Transfer RNA modification status influences retroviral ribosomal frameshifting

The possibility of whether tRNAs with and without a highly modified base in their anticodon loop may influence the level of retroviral ribosomal frameshifting was examined. Rabbit reticulocyte lysates were programmed with mRNA encoding UUU or AAC at the frameshift site and the corresponding Phe tRNA with or without the highly modified wyebutoxine (Y) base on the 3' side of its anticodon or Asn tRNA with or without the highly modified queuine (Q) base in the wobble position of its anticodon added. Phe and Asn tRNAs without the Y or Q base, respectively, stimulated the level of frameshifting, suggesting that the frameshift event is influenced by tRNA modification status. In addition, when AAU occurred immediately upstream of UUU as the penultimate frameshift site codon, addition of tRNAAsn without the Q base reduced the stimulatory effect of tRNAPhe without the Y base, whereas addition of tRNAAsn with the Q base did not alter the stimulatory effect. The addition of tRNAAsn without the Q base and tRNAPhe with the Y base inhibited frameshifting. The latter studies suggest an interplay between the tRNAs decoded at the penulimate frameshift and frameshift site codons that is also influenced by tRNA modification status. These data may be intrepreted as indicating that a hypomodified isoacceptor modulates frameshifting in an upward manner when utilized at the frameshift site codon, but modulates frameshifting in a downward manner when utilized at the penultimate frameshift site codon.

The effect of queuosine on tRNA structure and function

Computational modeling was performed to determine the potential function of the queuosine modification of tRNA found in wobble position 34 of tRNAasp, tRNAasn, tRNAhis, and tRNAtyr. Using the crystal structure of tRNAasp and a tRNA-tRNA-mRNA complex model, we show that the queuosine modification serves as a structurally restrictive base for tRNA anticodon loop flexibility. An extended intraresidue and intramolecular hydrogen bonding network is established by queuosine. The quaternary amine of the 7-aminomethyl side chain hydrogen bonds with the base's carbonyl oxygen. This positions the dihydroxycyclopentenediol ring of queuosine in proper orientation for hydrogen bonding with the backbone of the neighboring uridine 33 residue. The interresidue association stabilizes the formation of a cross-loop hydrogen bond between the uridine 33 base and the phosphoribosyl backbone of the cytosine at position 36. Additional interactions between RNAs in the translation complex were studied with regard to potential codon context and codon bias effects. Neither steric nor electrostatic interaction occurs between aminoacyl- and peptidyl-site tRNA anticodon loops that are modified with queuosine. However, there is a difference in the strength of anticodon/codon associations (codon bias) based on the presence or lack of queuosine in the wobble position of the tRNA. Unmodified (guanosine-containing) tRNAasp forms a very stable association with cytosine (GAC), but is much less stable in complex with a uridine-containing codon (GAU). Queuosine-modified tRNAasp exhibits no bias for either of cognate codons GAC or GAU and demonstrates a lower binding energy similar to the wobble pairing of guanosine-containing tRNA with a GAU codon. This is proposed to be due to the inflexibility of the queuosine-modified anticodon loop to accommodate proper positioning for optimal Watson-Crick type associations. A preliminary survey of codon usage patterns in oncodevelopmental versus housekeeping gene transcripts suggests a significant difference in bias for the queuosine-associated codons. Therefore, the queuosine modification may have the potential to influence cellular growth and differentiation by codon bias-based regulation of protein synthesis for discrete mRNA transcripts.

Misreading of the argI message in Escherichia coli

It has previously been shown that either phenylalanine codon, UUU or UUC, could be misread as leucine during phenylalanine starvation, if the codons encoded residue 8 of the Escherichia coli argI gene product, ornithine transcarbamylase (OTC). However, no leucine misincorporation was detected when either of these same codons encoded residue 3. Here we report that leucine misincorporation can be directed by a UUU codon for residue 3 of OTC during phenylalanine starvation, if the argI gene has been mutated so that the codon preceding the UUU has been changed from the rarely used glycine codon GGG to the more commonly used GGC.

Translational suppression in retroviral gene expression

This chapter summarizes the present state of knowledge concerning translational suppression in retroviruses. Other viruses, using similar mechanisms, are mentioned only briefly and tangentially. Retroviruses are a unique class of viruses that have been found in all classes of vertebrates but not in other organisms. Perhaps, their most distinctive properties are the flow of information from RNA to DNA early in the infectious process, and the subsequent integration of the viral DNA into the chromosomal DNA of the host cell. Retroviruses are the causative agents of acquired immunodeficiency syndrome (AIDS) and of a variety of neoplastic diseases in man and domestic animals. Elements with striking similarities to retroviruses, termed retrotransposons, occur in yeast and many other eukaryotes; elements sharing some characteristics with retroviruses have also recently been observed in prokaryotes. Because of the apparent relationship between retroviruses and retrotransposons, this chapter discusses of retrotransposons as well as retroviruses. Though all retroviruses utilize translational suppression in pol-protein synthesis, different groups of retroviruses use two completely distinct types of translational suppression. One of these is in-frame or readthrough suppression and the other is ribosomal frameshifting.

Chromatographic analysis of the aminoacyl-tRNAs which are required for translation of codons at and around the ribosomal frameshift sites of HIV, HTLV-1, and BLV

An examination of the frameshift signals or proposed signals within published sequences of retroviruses and other genetic elements from higher animals shows that each site utilizes a tRNA which normally contains Wybutoxine (Wye) base or Queuine (Q) base in the anticodon loop. We find experimentally that most of the Phe-tRNA present in HIV-1 infected cells lacks the highly modified Wye base in its anticodon loop and most of the Asn-tRNA in HTLV-1 and BLV infected cells lacks the highly modified Q base in its anticodon loop. Interestingly, Phe-tRNA translates a UUU codon within the ribosomal frameshift signal in HIV and Asn-tRNA translates a AAC codon within the proposed frameshift signals in HTLV-1 and BLV. Thus, the lack of a highly modified base in the anticodon loop of tRNAs in retroviral infected cells is correlated with the participation of these undermodified tRNAs in the corresponding frameshift event. This suggests that the "shifty" tRNAs proposed by Jacks et al. (Cell 55, 447-458, 1988) to carry out frameshifting may be hypomodified isoacceptors.

Presence of the hypermodified nucleotide N6-(delta 2-isopentenyl)-2-methylthioadenosine prevents codon misreading by Escherichia coli phenylalanyl-transfer RNA

The overall structure of transfer RNA is optimized for its various functions by a series of unique post-transcriptional nucleotide modifications. Since many of these modifications are conserved from prokaryotes through higher eukaryotes, it has been proposed that most modified nucleotides serve to optimize the ability of the tRNA to accurately interact with other components of the protein synthesizing machinery. When a cloned synthetic Escherichia coli tRNAPhe gene was transfected into a bacterial host that carried a defective phenylalanine tRNA-synthetase gene, tRNAPhe was overexpressed by 11-fold. As a result of this overexpression, an undermodified tRNAPhe species was produced that lacked only N6-(delta 2-isopentenyl)-2-methylthioadenosine (ms2i6A), a hypermodified nucleotide found immediately 3' to the anticodon of all major E. coli tRNAs that read UNN codons. To investigate the role of ms2i6A in E. coli tRNA, we compared the aminoacylation kinetics and in vitro codon-reading properties of the ms2i6A-lacking and normal fully modified tRNAPhe species. The results of these experiments indicate that while ms2i6A is not required for normal aminoacylation of tRNAPhe, its presence stabilizes codon-anticodon interaction and thereby prevents misreading of the genetic code.