The split genes of Nanoarchaeum equitans are an ancestral character

The introns early hypothesis predicts that introns were fundamental in assembling the first genes. In Nanoarchaeum equitans some genes are split into two. If these split genes were the ancestral forms, as suggested by the introns early hypothesis, then the end-beginning of the two parts of the split protein in a multiple alignment with the orthologous proteins from the Eukarya and Arachaea domains should make a clear prediction on where the intron in the homologous eukaryotic gene should be positioned. The analysis has shown that the introns are in this position, which is therefore predictable on the basis of the split proteins of N. equitans. This corroborates the hypothesis that the split genes of N. equitans are the plesiomorphic forms of these genes. If true, this would show that the origin of genes was polyphyletic as the monophyletic origin hypothesis would deny the existence, in a real organism, of these ancestral (split) genes, which imply that they were assembled late on and after the domains of life were established. Furthermore, it would seem that hyperthermophily is also an ancestral trait because it is linked to a split gene in N. equitans.     

Gene transfers from nanoarchaeota to an ancestor of diplomonads and parabasalids

Rare evolutionary events, such as lateral gene transfers and gene fusions, may be useful to pinpoint, and correlate the timing of, key branches across the tree of life. For example, the shared possession of a transferred gene indicates a phylogenetic relationship among organismal lineages by virtue of their shared common ancestral recipient. Here, we present phylogenetic analyses of prolyl-tRNA and alanyl-tRNA synthetase genes that indicate lateral gene transfer events to an ancestor of the diplomonads and parabasalids from lineages more closely related to the newly discovered archaeal hyperthermophile Nanoarchaeum equitans (Nanoarchaeota) than to Crenarchaeota or Euryarchaeota. The support for this scenario is strong from all applied phylogenetic methods for the alanyl-tRNA sequences, whereas the phylogenetic analyses of the prolyl-tRNA sequences show some disagreements between methods, indicating that the donor lineage cannot be identified with a high degree of certainty. However, in both trees, the diplomonads and parabasalids branch together within the Archaea, strongly suggesting that these two groups of unicellular eukaryotes, often regarded as the two earliest independent offshoots of the eukaryotic lineage, share a common ancestor to the exclusion of the eukaryotic root. Unfortunately, the phylogenetic analyses of these two aminoacyl-tRNA synthetase genes are inconclusive regarding the position of the diplomonad/parabasalid group within the eukaryotes. Our results also show that the lineage leading to Nanoarchaeota branched off from Euryarchaeota and Crenarchaeota before the divergence of diplomonads and parabasalids, that this unexplored archaeal diversity, currently only represented by the hyperthermophilic organism Nanoarchaeum equitans, may include members living in close proximity to mesophilic eukaryotes, and that the presence of split genes in the Nanoarchaeum genome is a derived feature.     

Evolutionary and functional genomics of the Archaea

In the past two years, archaeal genomics has achieved several breakthroughs. On the evolutionary front the most exciting development was the sequencing and analysis of the genome of Nanoarchaeum equitans, a tiny parasitic organism that has only approximately 540 genes. The genome of Nanoarchaeum shows signs of extreme rearrangement including the virtual absence of conserved operons and the presence of several split genes. Nanoarchaeum is distantly related to other archaea, and it has been proposed to represent a deep archaeal branch that is distinct from Euryarchaeota and Crenarchaeota. This would imply that many features of its gene repertoire and genome organization might be ancestral. However, additional genome analysis has provided a more conservative suggestion - that Nanoarchaeum is a highly derived euryarchaeon. Also there have been substantial developments in functional genomics, including the discovery of the elusive aminoacyl-tRNA synthetase that is involved in both the biosynthesis of cysteine and its incorporation into proteins in methanogens, and the first experimental validation of the predicted archaeal exosome.     

The non-monophyletic origin of the tRNA molecule and the origin of genes only after the evolutionary stage of the last universal common ancestor (LUCA)

A model has been proposed suggesting that the tRNA molecule must have originated by direct duplication of an RNA hairpin structure [Di Giulio, M., 1992. On the origin of the transfer RNA molecule. J. Theor. Biol. 159, 199-214]. A non-monophyletic origin of this molecule has also been theorized [Di Giulio, M., 1999. The non-monophyletic origin of tRNA molecule. J. Theor. Biol. 197, 403-414]. In other words, the tRNA genes evolved only after the evolutionary stage of the last universal common ancestor (LUCA) through the assembly of two minigenes codifying for different RNA hairpin structures, which is what the exon theory of genes suggests when it is applied to the model of tRNA origin. Recent observations strongly corroborate this theorization because it has been found that some tRNA genes are completely separate in two minigenes codifying for the 5' and 3' halves of this molecule [Randau, L., et al., 2005a. Nanoarchaeum equitans creates functional tRNAs from separate genes for their 5'- and 3'-halves. Nature 433, 537-541]. In this paper it is shown that these tRNA genes codifying for the 5' and 3' halves of this molecule are the ancestral form from which the tRNA genes continuously codifying for the complete tRNA molecule are thought to have evolved. This, together with the very existence of completely separate tRNA genes codifying for their 5' and 3' halves, proves a non-monophyletic origin for tRNA genes, as a monophyletic origin would exclude the existence of these genes which have, on the contrary, been observed. Here the polyphyletic origin of genes codifying for proteins is also suggested and discussed. Moreover, a hypothesis is advanced to suggest that the LUCA might have had a fragmented genome made up of RNA and the possibility that 'Paleokaryotes' may exist is outlined. Finally, the characteristic of the indivisibility of homology that these polyphyletic origins seem to remove at the sequence level is discussed.     

The complete set of tRNA species in Nanoarchaeum equitans

The archaeal parasite Nanoarchaeum equitans was found to generate five tRNA species via a unique process requiring the assembly of seperate 5' and 3' tRNA halves [Randau, L., Munch, R., Hohn, M.J., Jahn, D. and Soll, D. (2005) Nanoarchaeum equitans creates functional tRNAs from separate genes for their 5'- and 3'-halves. Nature 433, 537-541]. Biochemical evidence was missing for one of the computationally-predicted, joined tRNAs designated as tRNA(Trp). Our RT-PCR and sequencing results identify this tRNA as tRNA(Lys) (CUU) joined at the alternative position between bases 30 and 31. We show that the intron-containing tRNA(Trp) was misidentified in the initial Nanoarchaeum equitans genome annotation [E. Waters et al. (2003) The genome of Nanoarchaeum equitans: insights into early archaeal evolution and derived parasitism. Proc. Natl. Acad. Sci. USA 100, 12984-12988]. Along with a previously unidentified joined tRNA(Gln) (UUG), Nanoarchaeum equitans exhibits 44 tRNAs and is enabled to read all 61 sense codons. Features unique to this set of tRNA molecules are discussed.     

RNA processing in the minimal organism Nanoarchaeum equitans

ABSTRACT: BACKGROUND: The minimal genome of the tiny, hyperthermophilic archaeon Nanoarchaeum equitans contains several fragmented genes and revealed unusual RNA processing pathways. These include the maturation of tRNA molecules via the trans-splicing of tRNA halves and genomic rearrangements to compensate for the absence of RNase P. RESULTS: Here, the RNA processing events in the N. equitans cell are analyzed using RNA-Seq deep sequencing methodology. All tRNA half precursor and tRNA termini were determined and support the tRNA trans-splicing model. The processing of CRISPR RNAs from two CRISPR clusters was verified. Twenty-seven C/D box small RNAs (sRNAs) and a H/ACA box sRNA were identified. The C/D box sRNAs were found to flank split genes, to form dicistronic tRNA-sRNA precursors and to be encoded within the tRNAMet intron. CONCLUSIONS: The presented data provide an overview of the production and usage of small RNAs in a cell that has to survive with a highly reduced genome. N. equitans lost many essential metabolic pathways but maintains highly active CRISPR/Cas and rRNA modification systems that appear to play an important role in genome fragmentation.     

Nanoarchaeum equitans and Ignicoccus hospitalis: new insights into a unique, intimate association of two archaea

Nanoarchaeum equitans and Ignicoccus hospitalis represent a unique, intimate association of two archaea. Both form a stable coculture which is mandatory for N. equitans but not for the host I. hospitalis. Here, we investigated interactions and mutual influence between these microorganisms. Fermentation studies revealed that during exponential growth only about 25% of I. hospitalis cells are occupied by N. equitans cells (one to three cells). The latter strongly proliferate in the stationary phase of I. hospitalis, until 80 to 90% of the I. hospitalis cells carry around 10 N. equitans cells. Furthermore, the expulsion of H2S, the major metabolic end product of I. hospitalis, by strong gas stripping yields huge amounts of free N. equitans cells. N. equitans had no influence on the doubling times, final cell concentrations, and growth temperature, pH, or salt concentration ranges or optima of I. hospitalis. However, isolation studies using optical tweezers revealed that infection with N. equitans inhibited the proliferation of individual I. hospitalis cells. This inhibition might be caused by deprivation of the host of cell components like amino acids, as demonstrated by 13C-labeling studies. The strong dependence of N. equitans on I. hospitalis was affirmed by live-dead staining and electron microscopic analyses, which indicated a tight physiological and structural connection between the two microorganisms. No alternative hosts, including other Ignicoccus species, were accepted by N. equitans. In summary, the data show a highly specialized association of N. equitans and I. hospitalis which so far cannot be assigned to a classical symbiosis, commensalism, or parasitism.     

Shrinking genomics

Two bacteria are featured this month, and both are at the lower end of the genome size scale. The first, Mycoplasma gallisepticum, belongs to a group of bacteria that have been studied both as important human and animal pathogens and in the pursuit of understanding the essential functions of a self-replicating minimal cell. The second, Nanoarchaeum equitans, is an obligate symbiont that only grows in co-culture with another archaeon. N. equitans seems to be the coelacanth of the microbial world--it has been assigned to a new phylum and represents a primitive form of prokaroytic life.     

Proto-splice site model of intron origin

It is proposed that nuclear pre-mRNA introns (classical introns) were first generated as by-products during the evolution of alternative splicing. They were formed whenever two splice sites within the coding sequence of ancestral genes were used at a frequency that removed the coding constraint from the intervening sequence. Once introns had evolved, it is suggested that they were spread by the splicing machinery which inserted them into proto or cryptic-splice sites of other genes by reverse splicing, so giving rise to genes that have introns yet are not alternatively spliced. It is argued that 5' and 3' splice sites evolved from common ancestral splice sites, referred to as proto-splice sites, that were bidirectional and had a core consensus sequence of C or A, A, G, R, which remains today as the immediate flanking sequence of most introns. The ancestral splicing machinery, although inefficient, would have been capable of generating vast mRNA diversity by splicing between proto-splice sites. Natural selection would be expected to have preserved mutations that increased the amounts of advantageously spliced mRNA. It is argued that this process drove the evolution of present 5' and 3' splice sites from a subset of proto-splice sites and also drove the evolution of a more efficient splicing machinery. The positions of most introns that evolved directly from the coding sequence would be expected to correlate with protein structure.     

The major shifts of human duplicated genes

Since many gene duplications in the human genome are ancient duplications going back to the origin of vertebrates, the question may be asked about the fate of such duplicated genes at the compositional genome transitions that occurred between cold- and warm-blooded vertebrates. Indeed, at that transition, about half of the (GC-poor) genes of cold-blooded vertebrates (the genes of the gene-dense "ancestral genome core") underwent a GC enrichment to become the genes of the "genome core" of warm-blooded vertebrates. Since the compositional distribution of the human duplicated genes investigated (1111 pairs) mimics the general distribution of human genes (about 50% GC(3)-poor and 50% GC(3)-rich genes, the border being at 60% GC(3)), we considered two possibilities, namely that the compositional transition affected either (i) about half of the copies on a random basis, or (ii) preferentially only one copy of the duplicated genes. The two possibilities could be distinguished if each copy is put into one of two subsets according to its GC(3) level. Indeed, in the first case, the two distributions would be similar, whereas in the second case, the two distributions would be different, one copy having maintained the ancestral GC-poor composition, and one copy having undergone the compositional change. Using this approach, we could show that, by far and large, one copy of the duplicated genes preferentially underwent the GC enrichment. This result implies that this copy, which had possibly acquired a different function and/or regulation, was preferentially translocated into the gene-dense compartment of the genome, the "ancestral genome core", namely the "gene space" which underwent the compositional transition at the emergence of warm-blooded vertebrates.     

The slow road to the eukaryotic genome

The eukaryotic genome is a mosaic of eubacterial and archaeal genes in addition to those unique to itself. The mosaic may have arisen as the result of two prokaryotes merging their genomes, or from genes acquired from an endosymbiont of eubacterial origin. A third possibility is that the eukaryotic genome arose from successive events of lateral gene transfer over long periods of time. This theory does not exclude the endosymbiont, but questions whether it is necessary to explain the peculiar set of eukaryotic genes. We use phylogenetic studies and reconstructions of ancestral first appearances of genes on the prokaryotic phylogeny to assess evidence for the lateral gene transfer scenario. We find that phylogenies advanced to support fusion can also arise from a succession of lateral gene transfer events. Our reconstructions of ancestral first appearances of genes reveal that the various genes that make up the eukaryotic mosaic arose at different times and in diverse lineages on the prokaryotic tree, and were not available in a single lineage. Successive events of lateral gene transfer can explain the unusual mosaic structure of the eukaryotic genome, with its content linked to the immediate adaptive value of the genes its acquired. Progress in understanding eukaryotes may come from identifying ancestral features such as the eukaryotic splicesome that could explain why this lineage invaded, or created, the eukaryotic niche.     

Sequence evidence in the archaeal genomes that tRNAs emerged through the combination of ancestral genes as 5' and 3' tRNA halves

The discovery of separate 5' and 3' halves of transfer RNA (tRNA) molecules-so-called split tRNA-in the archaeal parasite Nanoarchaeum equitans made us wonder whether ancestral tRNA was encoded on 1 or 2 genes. We performed a comprehensive phylogenetic analysis of tRNAs in 45 archaeal species to explore the relationship between the three types of tRNAs (nonintronic, intronic and split). We classified 1953 mature tRNA sequences into 22 clusters. All split tRNAs have shown phylogenetic relationships with other tRNAs possessing the same anticodon. We also mimicked split tRNA by artificially separating the tRNA sequences of 7 primitive archaeal species at the anticodon and analyzed the sequence similarity and diversity of the 5' and 3' tRNA halves. Network analysis revealed specific characteristics of and topological differences between the 5' and 3' tRNA halves: the 5' half sequences were categorized into 6 distinct groups with a sequence similarity of >80%, while the 3' half sequences were categorized into 9 groups with a higher sequence similarity of >88%, suggesting different evolutionary backgrounds of the 2 halves. Furthermore, the combinations of 5' and 3' halves corresponded with the variation of amino acids in the codon table. We found not only universally conserved combinations of 5'-3' tRNA halves in tRNA(iMet), tRNA(Thr), tRNA(Ile), tRNA(Gly), tRNA(Gln), tRNA(Glu), tRNA(Asp), tRNA(Lys), tRNA(Arg) and tRNA(Leu) but also phylum-specific combinations in tRNA(Pro), tRNA(Ala), and tRNA(Trp). Our results support the idea that tRNA emerged through the combination of separate genes and explain the sequence diversity that arose during archaeal tRNA evolution.     

Regulatory genes in the ancestral chordate genomes

Changes or innovations in gene regulatory networks for the developmental program in the ancestral chordate genome appear to be a major component in the evolutionary process in which tadpole-type larvae, a unique characteristic of chordates, arose. These alterations may include new genetic interactions as well as the acquisition of new regulatory genes. Previous analyses of the Ciona genome revealed that many genes may have emerged after the divergence of the tunicate and vertebrate lineages. In this paper, we examined this possibility by examining a second non-vertebrate chordate genome. We conclude from this analysis that the ancient chordate included almost the same repertory of regulatory genes, but less redundancy than extant vertebrates, and that approximately 10% of vertebrate regulatory genes were innovated after the emergence of vertebrates. Thus, refined regulatory networks arose during vertebrate evolution mainly as preexisting regulatory genes multiplied rather than by generating new regulatory genes. The inferred regulatory gene sets of the ancestral chordate would be an important foundation for understanding how tadpole-type larvae, a unique characteristic of chordates, evolved.     

Hidden evolutionary complexity of Nucleo-Cytoplasmic Large DNA viruses of eukaryotes

ABSTRACT: BACKGROUND: The Nucleo-Cytoplasmic Large DNA Viruses (NCLDV) constitute an apparently monophyletic group that consists of at least 6 families of viruses infecting a broad variety of eukaryotic hosts. A comprehensive genome comparison and maximum-likelihood reconstruction of the NCLDV evolution revealed a set of approximately 50 conserved, core genes that could be mapped to the genome of the common ancestor of this class of eukaryotic viruses. RESULTS: We performed a detailed phylogenetic analysis of these core NCLDV genes and applied the constrained tree approach to show that the majority of the core genes are unlikely to be monophyletic. Several of the core genes have been independently acquired from different sources by different NCLDV lineages whereas for the majority of these genes displacement by homologs from cellular organisms in one or more groups of the NCLDV was demonstrated. CONCLUSIONS: A detailed study of the evolution of the genomic core of the NCLDV reveals substantial complexity and diversity of evolutionary scenarios that was largely unsuspected previously. The phylogenetic coherence between the core genes is sufficient to validate the hypothesis on the evolution of all NCLDV from a common ancestral virus although the set of ancestral genes might be smaller than previously inferred from patterns of gene presence-absence.     

Molecular phylogeny and evolution of the plastid and nuclear encoded cbbX genes in the unicellular red alga Cyanidioschyzon merolae

The cbbX gene is generally encoded in proteobacterial genomes and red-algal plastid genomes. In this study, we found two distinct cbbX genes of Cyanidioschyzon merolae, a unicellular red alga, one encoded in the plastid genome and the other encoded in the cell nucleus. The phylogenetic tree inferred from cbbX genes and strongly conserved gene organization (rbcLS-cbbX) suggests that the plastid-encoded cbbX gene of C. merolae came from an ancestral proteobacterium by horizontal gene transfer. On the other hand, the nuclear-encoded cbbX gene of C. merolae was classified in another cluster together with the nucleomorph-encoded cbbX gene of Guillardia theta. Furthermore, expression of the two cbbX genes were regulated differently in response to extracellular CO(2) concentration. Our results imply that cbbX gene in the plastid genome was copied and transferred to the cell nucleus after horizontal gene transfer of RuBisCo operon from ancestral beta-proteobacteria at comparatively early stage, and that each cbbX evolved in different ways.     

基于太平洋甲胁虱裂化线粒体基因组推测甲胁虱属祖先线粒体核型

[目的]动物典型的单一染色体线粒体基因组在甲胁虱属Hoplopleura已裂化成多个线粒体微环染色体.本研究旨在通过测定太平洋甲胁虱Hoplopleura pacifica的线粒体基因组来推测甲胁虱属祖先线粒体核型.[方法]利用Illumina HiSeq X Ten高通量测序技术对太平洋甲胁虱裂化线粒体基因组进行测定...     

Palaeophylogenomics of the vertebrate ancestor--impact of hidden paralogy on hagfish and lamprey gene phylogeny

In dissecting the transition from invertebrates to vertebrates at the molecular level, whole-genome duplications are recognized as a key event. This gave rise to more copies of genes in jawed vertebrates (gnathostomes), such as the four Hox clusters in the human, compared to the single ancestral cluster in invertebrates. To date, as the most early-branching lineages in vertebrates, cyclostomes (hagfishes and lampreys) have been used for comparative analyses of gene regulations and functions. However, assignment of orthology/paralogy for cyclostomes' genes is not unambiguously demonstrated. Thus, there is a high degree of incongruence in tree topologies between gene families, although whole genome duplications postulate uniform patterns in gene phylogeny. In this review, we demonstrate how expansion of an ancient genome before the cyclostome-gnathostome split, followed by reciprocal gene loss, can cause this incongruence. This is sometimes referred to as 'hidden paralogy'.