Origin and Evolution of RNA-Dependent RNA Polymerase (original) (raw)
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On the early evolution of RNA polymerase
Journal of Molecular Evolution, 1988
The lines of evidence suggesting that RNA preceded double-stranded DNA as an informational macromolecule are briefly reviewed. RNA polymerase is hypothesized to have been one of the earliest proteins to appear. It is argued that an important vestige of the original enzyme is found in the contemporary eubacterial β′ subunit of DNA-dependent RNA polymerase and its homologues among the archaebacterial and eukaryotic enzymes. The evidence that supports a catalytic role in replicase activity of this polypeptide is reviewed. It is suggested that several characteristics of theEscherichia coli transcriptional apparatus are relatively recent evolutionary developments. The phylogenetic importance of the eubacterial β′ subunit from RNA polymerase and its homologues is emphasized, because it allows the study of the evolutionary relationships of the major cellular lines (eubacteria, archaebacteria, and eukaryotes) as well as of some viral lineages.
Evolution of Tertiary Structure of Viral RNA Dependent Polymerases
PLoS ONE, 2014
Viral RNA dependent polymerases (vRdPs) are present in all RNA viruses; unfortunately, their sequence similarity is too low for phylogenetic studies. Nevertheless, vRdP protein structures are remarkably conserved. In this study, we used the structural similarity of vRdPs to reconstruct their evolutionary history. The major strength of this work is in unifying sequence and structural data into a single quantitative phylogenetic analysis, using powerful a Bayesian approach. The resulting phylogram of vRdPs demonstrates that RNA-dependent DNA polymerases (RdDPs) of viruses within Retroviridae family cluster in a clearly separated group of vRdPs, while RNA-dependent RNA polymerases (RdRPs) of dsRNA and +ssRNA viruses are mixed together. This evidence supports the hypothesis that RdRPs replicating +ssRNA viruses evolved multiple times from RdRPs replicating +dsRNA viruses, and vice versa. Moreover, our phylogram may be presented as a scheme for RNA virus evolution. The results are in concordance with the actual concept of RNA virus evolution. Finally, the methods used in our work provide a new direction for studying ancient virus evolution.
RNA Dependent RNA Polymerases: Insights from Structure, Function and Evolution
Viruses, 2018
RNA dependent RNA polymerase (RdRp) is one of the most versatile enzymes of RNA viruses that is indispensable for replicating the genome as well as for carrying out transcription. The core structural features of RdRps are conserved, despite the divergence in their sequences. The structure of RdRp resembles that of a cupped right hand and consists of fingers, palm and thumb subdomains. The catalysis involves the participation of conserved aspartates and divalent metal ions. Complexes of RdRps with substrates, inhibitors and metal ions provide a comprehensive view of their functional mechanism and offer valuable insights regarding the development of antivirals. In this article, we provide an overview of the structural aspects of RdRps and their complexes from the Group III, IV and V viruses and their structure-based phylogeny.
On the Evolution of the Single-Subunit RNA Polymerases
Journal of Molecular Evolution, 1997
Many eukaryotic nuclear genomes as well as mitochondrial plasmids contain genes displaying evident sequence similarity to those encoding the singlesubunit RNA polymerase (ssRNAP) of bacteriophage T7 and its relatives. We have collected and aligned these ssRNAP sequences and have constructed unrooted phylogenetic trees that demonstrate the separation of ssRNAPs into three well-defined and nonoverlapping clusters (phage-encoded, nucleus-encoded, and plasmidencoded). Our analyses indicate that these three subfamiles of T7-like RNAPs shared a common ancestor; however, the order in which the groups diverged cannot be inferred from available data. On the basis of structural similarities and mutational data, we suggest that the ancestral ssRNAP gene may have arisen via duplication and divergence of a DNA polymerase or reverse transcriptase gene. Considering the current phylogenetic distribution of ssRNAP sequences, we further suggest that the origin of the ancestral ssRNAP gene closely paralleled in time the introduction of mitochondria into eukaryotic cells through a eubacterial endosymbiosis.
Origins of Life and the RNA World: Evolution of RNA-Replicase Recognition
Symposium - International Astronomical Union, 2004
Central to understanding the origin of life is the elucidation of the first replication mechanism. The RNA World hypothesis suggests that the first self-replicating molecules were RNAs and that DNA later superceded RNA as the genetic material. RNA viruses were not subjected to the same evolutionary pressures as cellular organisms; consequently, they likely possess remnants of earlier replication strategies. Our laboratory investigates how members of the RNA virus family Bromoviridae can have structurally distinct 3' end tags yet are specifically recognized by conserved replication enzymes. This work addresses the idea that 3' tRNA tails were functionally replaced in some viruses by an RNA-protein complex. These viruses may serve as a timeline for the transition from the RNA world to DNA and protein based life.
Evolutionary origins and directed evolution of RNA
In vitro selection experiments show first and foremost that it is possible that functional nucleic acids can arise from random sequence libraries. Indeed, even simple sequence and structural motifs can prove to be robust binding species and catalysts, indicating that it may have been possible to transition from even the earliest self-replicators to a nascent, RNA-catalyzed metabolism. Because of the diversity of aptamers and ribozymes that can be selected, it is possible to construct a 'fossil record' of the evolution of the RNA world, with in vitro selected catalysts filling in as doppelgangers for molecules long gone. In this way a plausible pathway from simple oligonucleotide replicators to genomic polymerases can be imagined, as can a pathway from basal ribozyme activities to the ribosome. Most importantly, though, in vitro selection experiments can give a true and quantitative idea of the likelihood that these scenarios could have played out in the RNA world. Simple binding species and catalysts could have evolved into other structures and functions. As replicating sequences grew longer, new, more complex functions or faster catalytic activities could have been accessed. Some activities may have been isolated in sequence space, but others could have been approached along large, interconnected neutral networks. As the number, type, and length of ribozymes increased, RNA genomes would have evolved and eventually there would have been no area in a fitness landscape that would have been inaccessible. Self-replication would have inexorably led to life.
Structure and evolution of prokaryotic and eukaryotic RNA polymerases: a model
Journal of Theoretical Biology, 1987
A comparative overview of the subunit taxonomy and sequences of eukaryotic and prokaryotic RNA polymerases indicates the presence of a core structure conserved between both sets of enzymes. The differentiation between prokaryotic and eukaryotic polymerases is ascribed to domains and subunits peripheral to the largely conserved central structure. Possible subunit and domain functions are outlined. The core's flexible shape is largely determined by the elongated architecture of the two largest subunits, which can be oriented along the DNA axis with their bulkier amino-terminal head regions looking towards the 3' end of the gene to be transcribed and their more slender carboxyl-terminal domains at the tail end of the enzyme. The two largest prokaryotic subunits appear originally derived from a single gene.
Journal of Molecular Biology, 2002
Template-dependent polynucleotide synthesis is catalyzed by enzymes whose core component includes a ubiquitous ab palm subdomain comprising A, B and C sequence motifs crucial for catalysis. Due to its unique, universal conservation in all RNA viruses, the palm subdomain of RNAdependent RNA polymerases (RdRps) is widely used for evolutionary and taxonomic inferences. We report here the results of elaborated computer-assisted analysis of newly sequenced replicases from Thosea asigna virus (TaV) and the closely related Euprosterna elaeasa virus (EeV), insect-specific ssRNA þ viruses, which revise a capsid-based classification of these viruses with tetraviruses, an Alphavirus-like family. The replicases of TaV and EeV do not have characteristic methyltransferase and helicase domains, and include a putative RdRp with a unique C-A-B motif arrangement in the palm subdomain that is also found in two dsRNA birnaviruses. This circular motif rearrangement is a result of migration of , 22 amino acid (aa) residues encompassing motif C between two internal positions, separated by , 110 aa, in a conserved region of , 550 aa. Protein modeling shows that the canonical palm subdomain architecture of poliovirus (ssRNA þ) RdRp could accommodate the identified sequence permutation through changes in backbone connectivity of the major structural elements in three loop regions underlying the active site. This permutation transforms the ferredoxin-like b1aAb2-b3aBb4 fold of the palm subdomain into the b2b3b1aAaBb4 structure and brings b-strands carrying two principal catalytic Asp residues into sequential proximity such that unique structural properties and, ultimately, unique functionality of the permuted RdRps may result. The permuted enzymes show unprecedented interclass sequence conservation between RdRps of true ssRNA þ and dsRNA viruses and form a minor, deeply separated cluster in the RdRp tree, implying that other, as yet unidentified, viruses may employ this type of RdRp. The structural diversification of the palm subdomain might be a major event in the evolution of template-dependent polynucleotide polymerases in the RNA-protein world.