Herve Seligmann

is a significant pediatric pathogen responsible for bone and joint infections, occult bacteremia, and endocarditis in early childhood. Past efforts to detect this bacterium by culture and broad-range 16S rRNA gene polymerase chain reaction (PCR) assays from clinical specimens have proven unsatisfactory and were gradually let out for the benefit of specific real-time PCR tests targeting the gene and RTX locus of by the late 2000s. However, recent studies showed that real-time PCR (RT-PCR) assays targeting the sp. RTX locus that are currently available for the diagnosis of infection lack of specificity because they could not distinguish between and the recently described species. Furthermore, in silico analysis of the gene from a large collection of 45 strains showed that primers and probes from -based RT-PCR assays display a few mismatches with variations that may result in a decreased detection sensitivity, especially in paucibacillary clinical specimens. In order to provide an alte...

Homology of some RNAs with template DNA requires systematic exchanges between nucleotides. Such exchanges produce 'swinger' RNA along 23 bijective transformations (nine symmetric, X ↔ Y; and 14 asymmetric, X → Y → Z → X, for example A ↔ C and A → C → G → A, respectively). Here, analyses compare amino acids coded by swinger-transformed codons to those coded by untransformed codons, defining coding invariance after transformations. Swinger transformations cluster according to coding invariance in four groups characterized by transformations into cytosine (C = C, T → C, A → C, and G → C). C's central mutational coding role shows that swinger transformations constrained genetic code genesis. Coding invariance post-transformations correlate positively/negatively with mitochondrial swinger transcription/lepidosaurian body temperature. Presumably, low/high temperatures stabilize/revert rare swinger polymerization modes, producing long swinger sequences/point mutations, respecti...

We examine the hypothesis that template-free RNAs still form spontaneously, as they did at the origins of life, invade modern genomes, contribute new genetic material. Previously, analyses of RNA secondary structures suggested that some RNAs resembling ancestral (t)RNAs formed recently , other parasitic sequences cluster with rRNAs. Here positive control analyses of additional RNA secondary structures confirm ancestral and statuses of RNA grouped according to secondary structure. Viroids with branched stems resemble RNAs, rod-shaped viroids resemble rRNA secondary structures, independently of GC contents. 5' UTR leading regions of West Nile and Dengue flavivirid viruses resemble and rRNA structures, respectively. An RNA homologous with Megavirus, Dengue and West Nile genomes, copperhead snake microsatellites and levant cotton repeats, not templated by Mimivirus' genome, persists throughout Mimivirus' infection. Its secondary structure clusters with candidate RNAs. The sa...

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 siRNA and compared viral fitness and protein expression in silenced versus wild-type mimivirus. Silencing decreased growth rate but viral particle production at the end of the viral cycle was unaffected. A comparative proteomic approach using 2D-DIGE revealed deregulation of the expression of 32 proteins in silenced mimivirus, defined as up- or down-regulated. 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...

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 ev...

We present an evolutionary hypothesis assuming that signals marking nucleotide synthesis (DNA replication and RNA transcription) evolved from multi- to unidimensional structures, and were carried over from transcription to translation. This evolutionary scenario presumes that signals combining secondary and primary nucleotide structures are evolutionary transitions. Mitochondrial replication initiation fits this scenario. Some observations reported in the literature corroborate that several signals for nucleotide synthesis function in translation, and vice versa. (a) Polymerase-induced frameshift mutations occur preferentially at translational termination signals (nucleotide deletion is interpreted as termination of nucleotide polymerization, paralleling the role of stop codons in translation). (b) Stem-loop hairpin presence/absence modulates codon-amino acid assignments, showing that translational signals sometimes combine primary and secondary nucleotide structures (here codon and...

We herein report the isolation and characterization of 21 Gram-stain-negative strains cultivated from the oropharynx of healthy children in Israel and Switzerland. Initially described as small colony variants of Kingella kingae, phenotypic analysis, biochemical analysis, phylogenetic analysis based on sequencing of the partial 16S rRNA gene and five housekeeping genes (abcZ, adk, G6PD, groEL and recA), and whole genome sequencing and comparison between members of the genera Kingella and Neisseria provided evidence for assigning them to the genus Kingella. Cellular fatty acids included important amounts of C12 : 0, C14 : 0, C16 : 0 and C16 : 1n7. Digital DNA-DNA hybridization between the isolates Sch538T and K. kingae ATCC 23330T revealed relatedness of 19.9 %. Comparative analysis of 16S rRNA gene sequences available in GenBank allowed matches to strains isolated in the USA, suggesting a wider geographical distribution. A novel species named Kingella negevensis sp. nov. is proposed,...

Proteomic MS/MS mass spectrometry detections are usually biased towards peptides cleaved by experimentally added digestion enzyme(s). Hence peptides resulting from spontaneous degradation and natural proteolysis usually remain undetected. Previous analyses of tryptic human proteome data (cleavage after K, R) detected non-canonical tryptic peptides translated according to tetra- and pentacodons (codons expanded by silent mono- and dinucleotides), and from transcripts systematically (a) deleting mono-, dinucleotides after trinucleotides (delRNAs), (b) exchanging nucleotides according to 23 bijective transformations. Nine symmetric and fourteen asymmetric nucleotide exchanges (X ↔ Y, e.g. A ↔ C; and X → Y → Z → X, e.g. A → C → G → A) produce swinger RNAs. Here unbiased reanalyses of these proteomic data detect preferentially non-canonical tryptic peptides despite assuming random cleavage. Unbiased analyses couldn't reconstruct experimental tryptic digestion if most detected non-can...

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Usual DNA→RNA transcription exchanges T→U. Assuming different systematic symmetric nucleotide exchanges during translation, some GenBank RNAs match exactly human mitochondrial sequences (exchange rules listed in decreasing transcript frequencies): C↔U, A↔U, A↔U+C↔G (two nucleotide pairs exchanged), G↔U, A↔G, C↔G, none for A↔C, A↔G+C↔U, and A↔C+G↔U. Most unusual transcripts involve exchanging uracil. Independent measures of rates of rare replicational enzymatic DNA nucleotide misinsertions predict frequencies of RNA transcripts systematically exchanging the corresponding misinserted nucleotides. Exchange transcripts self-hybridize less than other gene regions, self-hybridization increases with length, suggesting endoribonuclease-limited elongation. Blast detects stop codon depleted putative protein coding overlapping genes within exchange-transcribed mitochondrial genes. These align with existing GenBank proteins (mainly metazoan origins, prokaryotic and viral origins underrepresented). These GenBank proteins frequently interact with RNA/DNA, are membrane transporters, or are typical of mitochondrial metabolism. Nucleotide exchange transcript frequencies increase with overlapping gene densities and stop densities, indicating finely tuned counterbalancing regulation of expression of systematic symmetric nucleotide exchange-encrypted proteins. Such expression necessitates combined activities of suppressor tRNAs matching stops, and nucleotide exchange transcription. Two independent properties confirm predicted exchanged overlap coding genes: discrepancy of third codon nucleotide contents from replicational deamination gradients, and codon usage according to circular code predictions. Predictions from both properties converge, especially for frequent nucleotide exchange types. Nucleotide exchanging transcription apparently increases coding densities of protein coding genes without lengthening genomes, revealing unsuspected functional DNA coding potential.

Triple-stranded DNA:RNA helices of unknown function in vertebrate mitochondria associate with replication and transcription. Antiparallel Hoogsteen pairings form triplexes at physiological conditions. Intermolecular antiparallel triplexes require inverted 3 0-to-5 0 RNA polymerization, which was never observed. Three rare, long natural 3 0-to-5 0 inverted Gen-Bank RNAs from mice mitochondria suggest occasional inverted transcription, putatively coding for proteins. BLAST aligns 18 GenBank-stored proteins with hypothetical proteins translated from the 3 0-to-5 0 inverted Mus musculus mitochondrial genome. Three are DNA-binding, five are membrane proteins. 25% of main frame codons contribute to their 3 0-to-5 0 overlap coding. Properties of these codons match those of overlap coding protein genes, as compared to codons not expected involved in inverted coding: a) nucleotide contents at synonymous codon positions in mitochondrial genomes fit replicational deamination gradients (A-> G and C-> T), but digress from gradients when functioning as nonsynonymous positions in putative 3 0-to-5 0 overlapping genes; b) bias against 'circular code' codons (codon groups creating unambiguity between frames), and favouring homogenous codons (AAA, CCC, GGG, TTT) characterize overlapping genes, including putative 3 0-to-5 0 overlapping genes, as compared to nonoverlapping coding sequences from the same main frame gene. This signature correlates with digression from deamination gradients. Deamination and circular code tests confirm independently alignment-based predictions of overlapping 3 0-to-5 0 protein coding genes. Results indicate varying expression for different 3 0-to-5 0 overlapping genes. Inverted 3 0-to-5 0 RNA is produced, perhaps by an unknown RNA polymerase (in-vertase) putatively coded by 3 0-to-5 0 inverted RNA.

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The hypothesis that tRNA sidearm loops bear anticodons assumes crossovers between anticodon and sidearms, or translation by expressed aminoacylated tRNA halves forming single stem-loops. Only the latter might require ribosomal adaptations. Drosophila mitochondrial codon usages coevolve with sidearm numbers bearing matching putative anticodons (comparing different codon families in one genome, macroevolution) and when comparing different genomes for single codon families (microevolution). Coevolution between Drosophila and yeast mitochondrial antisense tRNAs and codon usages partly confounds microevolutionary patterns for putative sidearm anticodons. Some tRNA sidearm loops have more than seven nucleotides, putative expanded anticodons potentially matching quadruplet codons (tetracodons, codons expanded by a fourth silent position, forming tetragenes (predicted by alignment analyses of Drosophila mitochondrial genomes)). Tetracodon numbers coevolve with expanded tRNA sidearm loops. Sidearm coevolution with amino acid usages and tetragenes occurs for putative anticodons in 5' and 3' sidearms loops (D and TΨC loops, respectively), are stronger for the D-loop. Results slightly favour isolated stem-loops upon crossover hypotheses. An alternative hypothesis, that patterns observed for sidearm 'anticodons' do not imply translational activity, but recognition signals for tRNA synthetases that aminoacylate tRNAs, is incompatible with tetracodon/tetra-anticodon coevolution. Hence analyses strengthen translational hypotheses for tRNA sidearm anticodons, tetragenes, and antisense tRNAs.

The C(3) self-complementary circular code X identified in genes of prokaryotes and eukaryotes is a set of 20 trinucleotides enabling reading frame retrieval and maintenance, i.e. a framing code (Arquès and Michel, 1996; Michel, 2012, 2013). Some mitochondrial RNAs correspond to DNA sequences when RNA transcription systematically exchanges between nucleotides (Seligmann, 2013a,b). We study here the 23 bijective transformation codes ΠX of X which may code nucleotide exchanging RNA transcription as suggested by this mitochondrial observation. The 23 bijective transformation codes ΠX are C(3) trinucleotide circular codes, seven of them are also self-complementary. Furthermore, several correlations are observed between the Reading Frame Retrieval (RFR) probability of bijective transformation codes ΠX and the different biological properties of ΠX related to their numbers of RNAs in GenBank's EST database, their polymerization rate, their number of amino acids and the chirality of amino acids they code. Results suggest that the circular code X with the functions of reading frame retrieval and maintenance in regular RNA transcription, may also have, through its bijective transformation codes ΠX, the same functions in nucleotide exchanging RNA transcription. Associations with properties such as amino acid chirality suggest that the RFR of X and its bijective transformations molded the origins of the genetic code's machinery.

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.

Assuming systematic exchanges between nucleotides (swinger RNAs) resolves genomic 'parenthood' of some orphan mitochondrial transcripts. Twenty-three different systematic nucleotide exchanges (bijective transformations) exist. Similarities between transcription and replication suggest occurrence of swinger DNA. GenBank searches for swinger DNA matching the 23 swinger versions of human and mouse mitogenomes detect only vertebrate mitochondrial swinger DNA for swinger type AT + CG (from five different studies, 149 sequences) matching three human and mouse mitochondrial genes: 12S and 16S ribosomal RNAs, and cytochrome oxidase subunit I. Exchange A<->T + C<->G conserves self-hybridization properties, putatively explaining swinger biases for rDNA, against protein coding genes. Twenty percent of the regular human mitochondrial 16S rDNA consists of short swinger repeats (from 13 exchanges). Swinger repeats could originate from recombinations between regular and swinger DNA: duplicated mitochondrial genes of the parthenogenetic gecko Heteronotia binoei include fewer short A<->T + C<->G swinger repeats than non-duplicated mitochondrial genomes of that species. Presumably, rare recombinations between female and male mitochondrial genes (and in parthenogenetic situations between duplicated genes), favors reverse-mutations of swinger repeat insertions, probably because most inserts affect negatively ribosomal function. Results show that swinger DNA exists, and indicate that swinger polymerization contributes to the genesis of genetic material and polymorphism.

Punctuation codons (starts, stops) delimit genes, reflect translation apparatus properties. Most codon reassignments involve punctuation. Here two complementary approaches classify natural genetic codes: (A) properties of amino acids assigned to codons (classical phylogeny), coding stops as X (A1, antitermination/suppressor tRNAs insert unknown residues), or as gaps (A2, no translation, classical stop); and (B) considering only punctuation status (start, stop and other codons coded as À1, 0 and 1 (B1); 0, À1 and 1 (B2, reflects ribosomal translational dynamics); and 1, À1, and 0 (B3, starts/stops as opposites)). All methods separate most mitochondrial codes from most nuclear codes; Gracilibacteria consistently cluster with metazoan mitochondria; mitochondria co-hosted with chloroplasts cluster with nuclear codes. Method A1 clusters the euplotid nuclear code with metazoan mitochondria; A2 separates euplotids from mitochondria. Firmicute bacteria Mycoplasma/Spiroplasma and Protozoan (and lower metazoan) mitochondria share codon-amino acid assignments. A1 clusters them with mitochondria, they cluster with the standard genetic code under A2: constraints on amino acid ambiguity versus punctuation-signaling produced the mitochondrial versus bacterial versions of this genetic code. Punctuation analysis B2 converges best with classical phylogenetic analyses, stressing the need for a unified theory of genetic code punctuation accounting for ribosomal constraints. ã 2015 Published by Elsevier Ireland Ltd.

Swinger DNAs are sequences whose homology with known sequences is detected only by assuming systematic exchanges between nucleotides. Nine symmetric (X5-4Y, i.e. A5-4C) and fourteen asymmetric (X-4Y-4Z, i.e. A-4C-4G) exchanges exist. All swinger DNA previously detected in GenBank follow the A5-4T+C5-4G exchange, while mitochondrial swinger RNAs distribute among different swinger types. Here different alignment criteria detect 87 additional swinger mitochondrial DNAs (86 from insects), including the first swinger gene embedded within a complete genome, corresponding to the mitochondrial 16S rDNA of the stonefly Kamimuria wangi. Other Kamimuria mt genome regions are ''regular'', stressing unanswered questions on (a) swinger polymerization regulation; (b) swinger 16S rDNA functions; and (c) specificity to rDNA, in particular 16S rDNA. Sharp switches between regular and swinger replication, together with previous observations on swinger transcription, suggest that swinger replication might be due to a switch in polymerization mode of regular polymerases and the possibility of swinger-encoded information, predicted in primordial genes such as rDNA.

During RNA transcription, DNA nucleotides A,C,G, T are usually matched by ribonucleotides A, C, G and U. However occasionally, this rule does not apply: transcript-DNA homologies are detectable only assuming systematic exchanges between ribonucleotides. Nine symmetric (X ↔ Y, e.g. A ↔ C) and fourteen asymmetric (X ↔ Y ↔ Z, e.g. A ↔ C ↔ G) exchanges exist, called swinger transcriptions. Putatively, polymerases occasionally stabilize in unspecified swinger conformations, possibly similar to transient conformations causing punctual misinsertions. This predicts chimeric transcripts, part regular, part swinger-transformed, reflecting polymerases switching to swinger polymerization conformation(s). Four chimeric Genbank transcripts (three from human mitochondrion and one murine cytosolic) are described here: (a) the 5' and 3' extremities reflect regular polymerization, the intervening sequence exchanges systematically between ribonucleotides (swinger rule G ↔ U, transcript (1), with sharp switches between regular and swinger sequences; (b) the 5' half is 'normal', the 3' half systematically exchanges ribonucleotides (swinger rule C ↔ G, transcript (2), with an intercalated sequence lacking homology; (c) the 3' extremity fits A ↔ G exchanges (10% of transcript length), the 5' half follows regular transcription; the intervening region seems a mix of regular and A ↔ G transcriptions (transcript 3); (d) murine cytosolic transcript 4 switches to A ↔ U + C ↔ G, and is fused with A ↔ U + C ↔ G swinger transformed precursor rRNA. In (c), each concomitant transcript 5' and 3' extremities match opposite genome strands. Transcripts 3 and 4 combine transcript fusions with partial swinger transcriptions. Occasional (usually sharp) switches between regular and swinger transcriptions reveal greater coding potential than detected until now, suggest stable polymerase swinger conformations.

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.

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.

Transcriptomes and proteomes include RNA and protein fragments not matching regular transcription/translation. Some 'non-canonical' mitochondrial transcripts match mitogenomes after assuming one among 23 systematic exchanges between nucleotides, producing swinger RNAs (nine symmetric, X↔Y, example C↔T; 14 asymmetric, X→Y→Z→X, example A→T→G→A) in GenBank's EST database. Here, reanalyzes of (a) public human mitochondrial transcriptome data (Illumina: RNA-seq) allowed to detect mitochondrial swinger RNAs for all 23 exchanges and (b) independent public human mitochondrial trypsinized proteomic mass spectrometry data allowed to detect peptides predicted from translation of parts of swinger-transformed mitogenomes covered by detected swinger reads. RNA-seq and previous EST swinger transcript data converge. Swinger RNA translation frequently inserts various amino acids at stop codons. Swinger RNA-peptide associations exist also for peptides matching systematically frameshifting translation, peptides entirely coded by tetra- and pentacodons (regular codons expanded by silent mononucleotides at 4th, and silent dinucleotides at 4th and 5th position(s), respectively). Swinger peptides differ from regular mitochondrial proteins: not membrane embedded, reflect warmer, anaerobic, low resource conditions, reminding a free-living ancestor. Tetra- and pentacoded peptides associate with low, high GC contents, respectively, suggesting expanded codon translations associate with thermic stresses. Results confirm experimentally predicted swinger, tetra- and pentacoded mitochondrial peptides, increasing mitogenomic coding density.

In mitochondria, secondary structures punctuate post-transcriptional RNA processing. Recently described transcripts match the human mitogenome after systematic deletions of every 4th, respectively every 4th and 5th nucleotides, called delRNAs. Here I explore predicted stem-loop hairpin formation by delRNAs, and their associations with delRNA transcription and detected peptides matching their translation. Despite missing 25, respectively 40% of the nucleotides in the original sequence, del-transformed sequences form significantly more secondary structures than corresponding randomly shuffled sequences, indicating biological function, independently of, and in combination with, previously detected delRNA and thereof translated peptides. Self-hybridization decreases delRNA abundances, indicating downregulation. Systematic deletions of the human mitogenome reveal new, unsuspected coding and structural informations.

The swinger-transformed human mitogenome bears excess palindromes. Some swinger transformations reveal homology of mt tRNA Ala and mt replication origin. Swinger palindromes associate with swinger transcripts. Last point suggests stem-loop hairpin punctuation, as for regular mt transcription. a b s t r a c t Stem-loop hairpins punctuate mitochondrial post-transcriptional processing. Regulation of mitochon-drial swinger transcription, transcription producing RNAs matching the mitogenome only assuming systematic exchanges between nucleotides (23 bijective transformations along 9 symmetric exchanges Xo 4Y, e.g. A o 4G, and 14 asymmetric exchanges X4Y 4Z 4X, e.g. A 4G4 C4 A) remains unknown. Does swinger RNA self-hybridization regulate swinger, as regular, transcription? Groups of 8 swinger transformations share canonical self-hybridization properties within each group, group 0 includes identity (regular) transcription. The human mitogenome has more stem-loop hairpins than randomized sequences for all groups. Group 2 transformations reveal complementarity of the light strand replication origin (OL) loop and a neighboring tRNA gene, detecting the longtime presumed OL/tRNA homology. Non-canonical G¼ U pairings in hairpins increases with swinger RNA detection. These results confirm biological relevancy of swinger-transformed DNA/RNA, independently of, and in combination with, previously detected swinger DNA/RNA and swinger peptides. Swinger-transformed mitogenomes include unsuspected multilayered information.

The chaetognaths constitute a small and enigmatic phylum of little marine invertebrates. Both nuclear and mitochondrial genomes have numerous originalities, some phylum-specific. Until recently, their mitogenomes seemed containing only one tRNA gene (trnMet), but a recent study found in two chaetognath mitogenomes two and four tRNA genes. Moreover, apparently two conspecific mitogenomes have different tRNA gene numbers (one and two). Reanalyses by tRNAscan-SE and ARWEN softwares of the five available complete chaetognath mitogenomes suggest numerous additional tRNA genes from different types. Their total number never reaches the 22 found in most other invertebrates using that genetic code. Predicted error compensation between codon-anticodon mismatch and tRNA misacylation suggests translational activity by tRNAs predicted solely according to secondary structure for tRNAs predicted by tRNAscan-SE, not ARWEN. Numbers of predicted stop-suppressor (antitermination) tRNAs coevolve with predicted overlapping, frameshifted protein coding genes including stop codons. Sequence alignments in secondary structure prediction with non-chaetognath tRNAs suggest that the most likely functional tRNAs are in intergenic regions, as regular mt-tRNAs. Due to usually short intergenic regions, generally tRNA sequences partially overlap with flanking genes. Some tRNA pairs seem templated by sense-antisense strands. Moreover, 16S rRNA genes, but not 12S rRNAs, appear as tRNA nurseries, as previously suggested for multifunctional ribosomal-like protogenomes.

Previous mass spectrometry analyses described human mitochondrial peptides entirely translated from swinger RNAs, RNAs where polymerization systematically exchanged nucleotides. Exchanges follow one among 23 bijective transformation rules, nine symmetric exchanges (X ↔ Y, e.g. A ↔ C) and fourteen asymmetric exchanges (X → Y → Z → X, e.g. A → C → G → A), multiplying by 24 DNA's protein coding potential. Abrupt switches from regular to swinger polymerization produce chimeric RNAs. Here, human mitochondrial proteomic analyses assuming abrupt switches between regular and swinger transcriptions, detect chimeric peptides, encoded by part regular, part swinger RNA. Contiguous regular- and swinger-encoded residues within single peptides are stronger evidence for translation of swinger RNA than previously detected, entirely swinger-encoded peptides: regular parts are positive controls matched with contiguous swinger parts, increasing confidence in results. Chimeric peptides are 200 × rarer than swinger peptides (3/100,000 versus 6/1000). Among 186 peptides with > 8 residues for each regular and swinger parts, regular parts of eleven chimeric peptides correspond to six among the thirteen recognized, mitochondrial protein-coding genes. Chimeric peptides matching partly regular proteins are rarer and less expressed than chimeric peptides matching non-coding sequences, suggesting targeted degradation of misfolded proteins. Present results strengthen hypotheses that the short mitogenome encodes far more proteins than hitherto assumed. Entirely swinger-encoded proteins could exist.

Mass spectra of human mitochondrial peptides match non-canonical transcripts systematically (a) deleting mono/din-ucleotides 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 bijec-tive 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.

During RNA transcription, DNA nucleotides A,C,G, T are usually matched by ribonucleotides A, C, G and U. However occasionally, this rule does not apply: transcript-DNA homologies are detectable only assuming systematic exchanges between ribonucleotides. Nine symmetric (X ↔ Y, e.g. A ↔ C) and fourteen asymmetric (X ↔ Y ↔ Z, e.g. A ↔ C ↔ G) exchanges exist, called swinger transcriptions. Putatively, polymerases occasionally stabilize in unspecified swinger conformations, possibly similar to transient conformations causing punctual misinsertions. This predicts chimeric transcripts, part regular, part swinger-transformed, reflecting polymerases switching to swinger polymerization conformation(s). Four chimeric Genbank transcripts (three from human mitochondrion and one murine cytosolic) are described here: (a) the 5&amp;amp;amp;amp;amp;#39; and 3&amp;amp;amp;amp;amp;#39; extremities reflect regular polymerization, the intervening sequence exchanges systematically between ribonucleotides (swinger rule G ↔ U, transcript (1), with sharp switches between regular and swinger sequences; (b) the 5&amp;amp;amp;amp;amp;#39; half is &amp;amp;amp;amp;amp;#39;normal&amp;amp;amp;amp;amp;#39;, the 3&amp;amp;amp;amp;amp;#39; half systematically exchanges ribonucleotides (swinger rule C ↔ G, transcript (2), with an intercalated sequence lacking homology; (c) the 3&amp;amp;amp;amp;amp;#39; extremity fits A ↔ G exchanges (10% of transcript length), the 5&amp;amp;amp;amp;amp;#39; half follows regular transcription; the intervening region seems a mix of regular and A ↔ G transcriptions (transcript 3); (d) murine cytosolic transcript 4 switches to A ↔ U + C ↔ G, and is fused with A ↔ U + C ↔ G swinger transformed precursor rRNA. In (c), each concomitant transcript 5&amp;amp;amp;amp;amp;#39; and 3&amp;amp;amp;amp;amp;#39; extremities match opposite genome strands. Transcripts 3 and 4 combine transcript fusions with partial swinger transcriptions. Occasional (usually sharp) switches between regular and swinger transcriptions reveal greater coding potential than detected until now, suggest stable polymerase swinger conformations.