Evolution of small and large ribosomal RNAs from accretion of tRNA subelements.

tRNAs presumably accreted into modern ribosomal RNAs. Previous analyses showed similar secondary structures for ancient rRNA subelements and theoretical minimal RNA rings, candidate tRNA ancestors rationally designed from tRNA-unrelated principles. Here, analyses test which tRNA secondary structure subelements resemble ancient/recent rRNA subelements. Results show that ribosomal RNA subelements evolved from structures resembling 1. Upper half part of the tRNA secondary structure; and 2. Towards structures resembling (a) tRNA 5' stem-loop hairpins in large rRNA subunit and (b) tRNA lower half part in small rRNA subunit (stop and start codons conservation model). tRNAs and rRNAs presumably originated from the tRNA upper half part including the acceptor stem. Modern split 5' and 3' tRNA genes (spliced at anticodons) apparently reproduce ancestral-like states, because the acceptor stem protocode suggests acceptor stems evolved from spliced anticodon-like stem-loop hairpins, strengthening central roles for acceptor stem CCA-addition at translation origins. The Root-Bernstein hypothesis on the existence of tRNA structural symmetries presumably reflects late 5' tRNA stem-loop hairpin duplications, some integrating rRNAs. Analyses of tRNA subelements similarities with rRNA subelements suggest tRNAs evolved and re-evolved by different duplication-fusions, along different structural subdivision models. Hence, sequential/parallel processes, perhaps in the same ancestral organism(s) produced polyphyletic tRNAs. Results confirm RNA ring usefulness for understanding prebiotic and early life evolution, and their similarities with primordial protein coding and tRNA genes.

Systematic Nucleotide Exchange Analysis of ESTs From the Human Cancer Genome Project Report: Origins of 347 Unknown ESTs Indicate Putative Transcription of Non-Coding Genomic Regions.

Expressed sequence tags (ESTs) provide an imprint of cellular RNA diversity irrespectively of sequence homology with template genomes. NCBI databases include many unknown RNAs from various normal and cancer cells. These are usually ignored assuming sequencing artefacts or contamination due to their lack of sequence homology with template DNA. Here, we report genomic origins of 347 ESTs previously assumed artefacts/unknown, from the FAPESP/LICR Human Cancer Genome Project. EST template detection uses systematic nucleotide exchange analyses called swinger transformations. Systematic nucleotide exchanges replace systematically particular nucleotides with different nucleotides. Among 347 unknown ESTs, 51 ESTs match mitogenome transcription, 17 and 2 ESTs are from nuclear chromosome non-coding regions, and uncharacterized nuclear genes. Identified ESTs mapped on 205 protein-coding genes, 10 genes had swinger RNAs in several biosamples. Whole cell transcriptome searches for 17 ESTs mapping on non-coding regions confirmed their transcription. The 10 swinger-transcribed genes identified more than once associate with cancer induction and progression, suggesting swinger transformation occurs mainly in highly transcribed genes. Swinger transformation is a unique method to identify noncanonical RNAs obtained from NGS, which identifies putative ncRNA transcribed regions. Results suggest that swinger transcription occurs in highly active genes in normal and genetically unstable cancer cells.

Identification of Noncanonical Transcripts Produced by Systematic Nucleotide Exchanges in HIV-Associated Centroblastic Lymphoma.

Noncanonical transcriptions include transcriptions that systematically exchange nucleotides, also called bijective transformations or swinger transformations. Swinger transformation A↔T+C↔G recovers identities of 8 among 9 unknown RNAs differentially expressed in centroblastic lymphoma, a human immunodeficiency virus (HIV)-associated non-Hodgkin's lymphoma. The identified RNAs align with human genes with known anti-HIV1 or oncogenic activities. Function disruption through swinger-transformed transcription potentially enables avoiding antiviral responses and contributes to cancer induction.

Syntenies Between Cohosted Mitochondrial, Chloroplast, and Phycodnavirus Genomes: Functional Mimicry and/or Common Ancestry?

Recent analyses suggest bacterial and/or mitochondrion-like ancestry for giant viruses (Megavirales sensu latu): amoeban mitochondrial gene arrangements resemble those of their candidate homologs in megaviral genomes. This presumed ancestral synteny decreases with genome size across megaviral families at large and within Poxviridae. In this study, analyses focus on Phycodnaviridae, a polyphyletic group of giant viruses infecting Haplophyta, Stramenopiles, and other algae, using syntenies between algal mitogene arrangements and chloroplast genomes and Rickettsia prowazekii as positive controls. Mitogene alignment qualities with Rickettsia are much higher than with viral genomes. Mitogenome synteny with some viruses is higher, for others lower than with Rickettsia, despite lower alignments qualities. In some algae, syntenies among cohosted chloroplast, virus, and mitochondrion are higher, in others lower than expected. This suggests gene order coevolution in cohosted genomes, different coregulations of organelle metabolisms for different algae, and viral mitogenome mimicry, to hijack organelle-committed cellular resources and/or escape cellular defenses/genetic immunity systems. This principle might explain high synteny between human mitochondria and the pathogenic endocellular alphaproteobacterium R. prowazekii beyond common ancestry. Results indicate that putative bacteria/mitochondrion-like genomic ancestors of Phycodnaviridae originated before or at the mitochondrion-bacteria split, and ulterior functional constraints on gene arrangements of cohosted genomes.

Theoretical minimal RNA rings recapitulate the order of the genetic code's codon-amino acid assignments.

BACKGROUND: Theoretical minimal RNA rings form stem-loop hairpins coding for each of the 20 amino acids and a stop, presumably mimicking life's first minimal coding and self-replicating RNAs. They resemble consensual tRNAs. Mean amino acid positions in proteins follow the genetic code's consensual amino acid inclusion order, a 5'-late-to-3'-early amino acid gradient. HYPOTHESIS: We translated minimal RNA rings to test whether translated peptides share that gradient with modern proteins, using a) ribosomal translation, non-overlapping consecutive codons; and b) frameless translation advancing nucleotide by nucleotide, producing partially overlapping codons. RESULTS: For frameless translation, most RNA rings code for a 5'-late-to-3'early amino acid gradient. Gradients indicate decreasing amino acid metabolic costs, from large to small amino acids. For ribosomal translation, the 5'-late-to-3'early amino acid gradient evolves from early to late RNA rings when ranked according to yields in Miller's experiment of their predicted anticodon's cognate amino acid. CONCLUSIONS: Simulations that produced in silico minimal RNA rings didn't account for coded amino acid properties. Yet, produced peptides remind actual proteins, and suggest ancestral frameless translation of partially overlapping trinucleotides advancing by single nucleotide steps, constrained by resource scarcity. Minimal RNA rings reflect the transition from frameless to ribosomal translation and are realistic candidates for ancestral tRNAs.

Tailed giant Tupanvirus possesses the most complete translational apparatus of the known virosphere.

Here we report the discovery of two Tupanvirus strains, the longest tailed Mimiviridae members isolated in amoebae. Their genomes are 1.44-1.51 Mb linear double-strand DNA coding for 1276-1425 predicted proteins. Tupanviruses share the same ancestors with mimivirus lineages and these giant viruses present the largest translational apparatus within the known virosphere, with up to 70 tRNA, 20 aaRS, 11 factors for all translation steps, and factors related to tRNA/mRNA maturation and ribosome protein modification. Moreover, two sequences with significant similarity to intronic regions of 18 S rRNA genes are encoded by the tupanviruses and highly expressed. In this translation-associated gene set, only the ribosome is lacking. At high multiplicity of infections, tupanvirus is also cytotoxic and causes a severe shutdown of ribosomal RNA and a progressive degradation of the nucleus in host and non-host cells. The analysis of tupanviruses constitutes a new step toward understanding the evolution of giant viruses.

Experimental Analysis of Mimivirus Translation Initiation Factor 4a Reveals Its Importance in Viral Protein Translation during Infection of Acanthamoeba polyphaga.

The Acanthamoeba polyphaga mimivirus is the first giant virus ever described, with a 1.2-Mb genome which encodes 979 proteins, including central components of the translation apparatus. One of these proteins, R458, was predicted to initiate translation, although its specific role remains unknown. We silenced the R458 gene using small interfering RNA (siRNA) and compared levels of viral fitness and protein expression in silenced versus wild-type mimivirus. Silencing decreased the growth rate, but viral particle production at the end of the viral cycle was unaffected. A comparative proteomic approach using two-dimensional difference-in-gel electrophoresis (2D-DIGE) revealed deregulation of the expression of 32 proteins in silenced mimivirus, which were defined as up- or downregulated. Besides revealing proteins with unknown functions, silencing R458 also revealed deregulation in proteins associated with viral particle structures, transcriptional machinery, oxidative pathways, modification of proteins/lipids, and DNA topology/repair. Most of these proteins belong to genes transcribed at the end of the viral cycle. Overall, our data suggest that the R458 protein regulates the expression of mimivirus proteins and, thus, that mimivirus translational proteins may not be strictly redundant in relation to those from the amoeba host. As is the case for eukaryotic initiation factor 4a (eIF4a), the R458 protein is the prototypical member of the ATP-dependent DEAD box RNA helicase mechanism. We suggest that the R458 protein is required to unwind the secondary structures at the 5' ends of mRNAs and to bind the mRNA to the ribosome, making it possible to scan for the start codon. These data are the first experimental evidence of mimivirus translation-related genes, predicted to initiate protein biosynthesis.IMPORTANCE The presence in the genome of a mimivirus of genes coding for many translational processes, with the exception of ribosome constituents, has been the subject of debate since its discovery in 2003. In this work, we focused on the R458 mimivirus gene, predicted to initiate protein biosynthesis. After silencing was performed, we observed that it has no major effect on mimivirus multiplication but that it affects protein expression and fitness. This suggests that it is effectively used by mimivirus during its developmental cycle. Until large-scale genetic manipulation of giant viruses becomes possible, the silencing strategy used here on mimivirus translation-related factors will open the way to understanding the functions of these translational genes.

Reviewing evidence for systematic transcriptional deletions, nucleotide exchanges, and expanded codons, and peptide clusters in human mitochondria.

Polymerization sometimes transforms sequences by (a) systematic deletions of mono-, dinucleotides after trinucleotides, or (b) 23 systematic nucleotide exchanges (9 symmetric, X<>Y, e.g. G<>T, 14 asymmetric, X > Y > Z > X, e.g. A > G > T > A), producing del- and swinger RNAs. Some peptides correspond to del- and swinger RNA translations, also according to tetracodons, codons expanded by a silent nucleotide. Here new analyzes assume different proteolytic patterns, partially alleviating false negative peptide detection biases, expanding noncanonical mitoproteome profiles. Mito-genomic, -transcriptomic and -proteomic evidence for noncanonical transcriptions and translations are reviewed and clusters of del- and swinger peptides (also along tetracodons) are described. Noncanonical peptide clusters indicate regulated expression of cryptically encoded mitochondrial protein coding genes. These candidate noncanonical proteins don't resemble known proteins.

Natural mitochondrial proteolysis confirms transcription systematically exchanging/deleting nucleotides, peptides coded by expanded codons.

Protein sequences have higher linguistic complexities than human languages. This indicates undeciphered multilayered, overprinted information/genetic codes. Some superimposed genetic information is revealed by detections of transcripts systematically (a) exchanging nucleotides (nine symmetric, e.g. A<->C, fourteen asymmetric, e.g. A->C->G->A, swinger RNAs) translated according to tri-, tetra- and pentacodons, and (b) deleting mono-, dinucleotides after each trinucleotide (delRNAs). Here analyses of two independent proteomic datasets considering natural proteolysis confirm independently translation of these non-canonical RNAs, also along tetra- and pentacodons, increasing coverage of putative, cryptically encoded proteins. Analyses assuming endoproteinase GluC and elastase digestions (cleavages after residues D, E, and A, L, I, V, respectively) detect additional peptides colocalizing with detected non-canonical RNAs. Analyses detect fewer peptides matching GluC-, elastase- than trypsin-digestions: artificial trypsin-digestion outweighs natural proteolysis. Results suggest occurrences of complete proteins entirely matching non-canonical, superimposed encoding(s). Protein-coding after bijective transformations could explain genetic code symmetries, such as along Rumer's transformation.

Natural chymotrypsin-like-cleaved human mitochondrial peptides confirm tetra-, pentacodon, non-canonical RNA translations.

Mass spectra of human mitochondrial peptides match non-canonical transcripts systematically (a) deleting mono/dinucleotides after trinucleotides (delRNA), (b) exchanging nucleotides (swinger RNA), translated according to tri, (c) tetra- and pentacodons (codons expanded by a 4th (and 5th) silent nucleotide(s)). Swinger transcriptions are 23 bijective transformations, nine symmetric (X<->Y, e.g. A<->C) and fourteen asymmetric exchanges (X->Y->Z->X, e.g. A->C->G->A). Here, proteomic analyses assuming cleavage after W,Y, F (chymotrypsin-like, for trypsinized samples) detect fewer chymotrypsinized than trypsinized peptides. Detected non-canonical peptides map preferentially on detected non-canonical RNAs for chymotrypsinized peptides, as previously found for trypsinized peptides. This suggests residual natural chymotrypsin-like digestion detectable within experimentally trypsinized peptide data. Some trypsinized peptides are detected twice, by analyses assuming trypsin, and those assuming chymotrypsin cleavages. They have higher spectra counts than peptides detected only once, meaning that abundant peptides are more frequently detected, but detection certainties resemble those for peptides detected only once. Analyses assuming 'incorrect' digestions are inadequate negative controls for digestion enzymes naturally active in biological samples. Chymotrypsin-analyses confirm non-canonical transcriptions/translations independently of results obtained assuming trypsinization, increase non-canonical peptidome coverage, indicating mitogenome-encoding of yet undetected proteins.

Unifying view of stem-loop hairpin RNA as origin of current and ancient parasitic and non-parasitic RNAs, including in giant viruses.

Putatively, stem-loop RNA hairpins explain networks of selfish elements and RNA world remnants. Their genomic density increases with intracellular lifestyle, especially when comparing giant viruses and their virophages. RNA protogenomes presumably templated for mRNAs and self-replicating stem-loops, ancestors of modern genes and parasitic sequences, including tRNAs and rRNAs. Primary and secondary structure analyses suggest common ancestry for t/rRNAs and parasitic RNAs, parsimoniously link diverse RNA metabolites (replication origins, tRNAs, ribozymes, riboswitches, miRNAs and rRNAs) to parasitic RNAs (ribosomal viroids, Rickettsia repeated palindromic elements (RPE), stem-loop hairpins in giant viruses, their virophages, and transposable retrovirus-derived elements). Results indicate ongoing genesis of small RNA metabolites, and common ancestry or similar genesis for rRNA and retroviral sequences. Assuming functional integration of modular duplicated RNA hairpins evolutionarily unifies diverse molecules, postulating stem-loop hairpin RNAs as origins of genetic innovation, ancestors of rRNAs, retro- and Mimivirus sequences, and cells.

Codon expansion and systematic transcriptional deletions produce tetra-, pentacoded mitochondrial peptides.

Genes include occasionally isolated codons with a fourth (and fifth) silent nucleotide(s). Assuming tetracodons, translated hypothetical peptides align with regular GenBank proteins; predicted tetracodons coevolve with predicted tRNAs with expanded anticodons in each mammal, Drosophila and Lepidosauria mitogenomes, GC contents and with lepidosaurian body temperatures, suggesting that expanded codons are an adaptation of translation to high temperature. Hypothetically, continuous stretches of tetra- and pentacodons code for peptides. Both systematic nucleotide deletions during transcription, and translation by tRNAs with expanded anticodons could produce these peptides. Reanalyses of human nanoLc mass spectrometry peptidome data detect numerous tetra- and pentapeptides translated from the human mitogenome. These map preferentially on (BLAST-detected) human RNAs matching the human mitogenome, assuming systematic mono- and dinucleotide deletions after each third nucleotide (delRNAs). Translation by expanded anticodons is incompatible with silent nucleotides in the midst rather than at codon 3' extremity. More than 1/3 of detected tetra- and pentapeptides assume silent positions at codon extremity, suggesting that both mechanisms, regular translation of delRNAs and translation of regular RNAs by expanded anticodons, produce this peptide subgroup. Results show that systematically deleting polymerization occurs, and confirm serial translation of expanded codons. Non-canonical transcriptions and translations considerably expand the coding potential of DNA and RNA sequences.

Species radiation by DNA replication that systematically exchanges nucleotides?

RNA and DNA syntheses share many properties. Therefore, the existence of 'swinger' RNAs, presumed 'orphan' transcripts matching genomic sequences only if transcription systematically exchanged nucleotides, suggests replication producing swinger DNA. Transcripts occur in many short-lived copies, the few cellular DNA molecules are long-lived. Hence pressures for functional swinger DNAs are greater than for swinger RNAs. Protein coding properties of swinger sequences differ from original sequences, suggesting rarity of corresponding swinger DNA. For genes producing structural RNAs, such as tRNAs and rRNAs, three exchanges (A<->T, C<->G and A<->T+C<->G) conserve self-hybridization properties. All nuclear eukaryote swinger DNA sequences detected in GenBank are for rRNA genes assuming A<->T+C<->G exchanges. In brachyuran crabs, 25 species had A<->T+C<->G swinger 18S rDNA, all matching the reverse-exchanged version of regular 18S rDNA of a related species. In this taxon, swinger replication of 18S rDNA apparently associated with, or even resulted in species radiation. A<->T+C<->G transformation doesn't invert sequence direction, differing from inverted repeats. Swinger repeats (detectable only assuming swinger transformations, A<->T+C<->G swinger repeats most frequent) within regular human rRNAs, independently confirm swinger polymerizations for most swinger types. Swinger replication might be an unsuspected molecular mechanism for ultrafast speciation.

Systematic asymmetric nucleotide exchanges produce human mitochondrial RNAs cryptically encoding for overlapping protein coding genes.

GenBank's EST database includes RNAs matching exactly human mitochondrial sequences assuming systematic asymmetric nucleotide exchange-transcription along exchange rules: A→G→C→U/T→A (12 ESTs), A→U/T→C→G→A (4 ESTs), C→G→U/T→C (3 ESTs), and A→C→G→U/T→A (1 EST), no RNAs correspond to other potential asymmetric exchange rules. Hypothetical polypeptides translated from nucleotide-exchanged human mitochondrial protein coding genes align with numerous GenBank proteins, predicted secondary structures resemble their putative GenBank homologue's. Two independent methods designed to detect overlapping genes (one based on nucleotide contents analyses in relation to replicative deamination gradients at third codon positions, and circular code analyses of codon contents based on frame redundancy), confirm nucleotide-exchange-encrypted overlapping genes. Methods converge on which genes are most probably active, and which not, and this for the various exchange rules. Mean EST lengths produced by different nucleotide exchanges are proportional to (a) extents that various bioinformatics analyses confirm the protein coding status of putative overlapping genes; (b) known kinetic chemistry parameters of the corresponding nucleotide substitutions by the human mitochondrial DNA polymerase gamma (nucleotide DNA misinsertion rates); (c) stop codon densities in predicted overlapping genes (stop codon readthrough and exchanging polymerization regulate gene expression by counterbalancing each other). Numerous rarely expressed proteins seem encoded within regular mitochondrial genes through asymmetric nucleotide exchange, avoiding lengthening genomes. Intersecting evidence between several independent approaches confirms the working hypothesis status of gene encryption by systematic nucleotide exchanges.

Putative mitochondrial polypeptides coded by expanded quadruplet codons, decoded by antisense tRNAs with unusual anticodons.

Weak triplet codon-anticodon interactions render ribosome-free translation unlikely. Some modern tRNAs read quadruplet codons (tetracodons), suggesting vestigial ribosome-free translation. Here, mitochondrial genomes are explored for tetracoded overlapping protein coding (tetra)genes. Occasional single tetracodons within regular mitochondrial genes coevolve positively/negatively with antisense tRNAs with predicted reduced/expanded anticodons (depending on taxon), suggesting complex tetra-decoding mechanisms. Transcripts of antisense tRNAs with unusual anticodons are more abundant than of homologues with regular anticodons. Assuming overlapping tetracoding with silent 4th tetracodon position, BLAST aligns 10 putative tetragenes spanning 17% of regular human mitochondrial protein coding tricodons with 14 GenBank proteins. Various tests including predicted peptide secondary structures, 3rd codon position (of the regular main frame of the protein coding gene) conservation against replicational deamination mutation gradients, and circular code usage (overlapping genes avoid using circular code codons) confirm tetracoding in these overlapping tetragenes with silent 4th position, but not for BLAST-predicted tetragenes assuming silent 2nd or 3rd positions. This converges with tetradecoding mechanisms that are more compatible with silent 4th, than at other, tetracodon positions. Tetracoding increases with (a) GC-contents, perhaps conserved or switched on in high temperature conditions; (b) usage of theoretically predicted 'tessera' tetracodons; (c) 12s rRNA stability; and d) antisense tRNA numbers with predicted expanded anticodons. Most detected tetragenes are not evolutionarily conserved, apparently reflect specific, transient adaptations. Tetracoding increases with mammal longevity.

Overlapping genes coded in the 3'-to-5'-direction in mitochondrial genes and 3'-to-5' polymerization of non-complementary RNA by an 'invertase'.

Suppressor tRNAs induce expression of additional (off-frame) genes coded by stopless genetic codes without lengthening genomes, decreasing DNA replication costs. RNA 3'-to-5' polymerization by tRNAHis guanylyltransferase suggests further cryptic code: hypothetical 'invertases' polymerizing in the 3'-to-5' direction, advancing in the 5'-to-3' direction would produce non-complementary RNA templated by regular genes, with different coding properties. Assuming 'invertase' activity, BLAST analyses detect GenBank-stored RNA ESTs and proteins (some potentially coding for the hypothesized invertase) for human mitochondrial genes. These peptides' predicted secondary structures resemble their GenBank homologues'. 3'-to-5' EST lengths increase with their self-hybridization potential: Single-stranded RNA degradation perhaps limits 3'-to-5' elongation. Independent methods confirm predicted 3'-to-5' overlapping genes: (a) Presumed 3'-to-5' overlapping genes avoid codons belonging to circular codes; (b) Spontaneous replicational deamination (mutation) gradients occur at 3rd codon positions, unless these are involved in overlap coding, because mutations are counter selected in overlapping genes. Tests a and b converge on predicted 3'-to-5' gene expression levels. Highly expressed ones include also fewer stops, and mitochondrial genomes (in Primates and Drosophila) adapt to avoid dependence of 3'-to-5' coding upon antitermination tRNA activity. Secondary structure, circular code, gradient and coevolution analyses yield each clear positive results independently confirming each other. These positive results (including physical evidence for 3'-to-5' ESTs) indicate that 3'-to-5' coding and invertase activity is an a priori improbable working hypothesis that cannot be dismissed. Note that RNAs produced by invertases potentially produce triple-stranded DNA:RNA helices by antiparallel Hoogsteen pairings at physiological pH, as previously observed for mitochondrial genomes.